Agenda 06/19/2014 S PELICAN BAY SERVICES DIVISION
MUNICIPAL SERVICE TAXING & BENEFIT UNIT
NOTICE OF PUBLIC MEETING JUNE 19, 2014
THE PELICAN BAY SERVICES DIVISION BOARD WILL MEET IN A
SPECIAL SESSION THURSDAY, JUNE 19 AT 1 :00 PM AT THE
COMMUNITY CENTER AT PELICAN BAY, 8960 HAMMOCK OAK
DRIVE, NAPLES.
AGENDA
1. Pledge of Allegiance
2. Roll call
3. Agenda approval
4. Audience comments
5. * Approval of Clam Bay NRPA 10-year Management Plan
6. Next Meeting
7. Adjourn
*Asterisk indicates possible Board action item
ANY PERSON WISHING TO SPEAK ON AN AGENDA ITEM WILL RECEIVE UP TO ONE (1) MINUTE
PER ITEM TO ADDRESS THE BOARD. THE BOARD WILL SOLICIT PUBLIC COMMENTS ON
SUBJECTS NOT ON THIS AGENDA AND ANY PERSON WISHING TO SPEAK WILL RECEIVE UP TO
THREE (3) MINUTES.THE BOARD ENCOURAGES YOU TO SUBMIT YOUR COMMENTS IN WRITING
IN ADVANCE OF THE MEETING. ANY PERSON WHO DECIDES TO APPEAL A DECISION OF THIS
BOARD WILL NEED A RECORD OF THE PROCEEDING PERTAINING THERETO, AND THEREFORE
MAY NEED TO ENSURE THAT A VERBATIM RECORD IS MADE, WHICH INCLUDES THE
TESTIMONY AND EVIDENCE UPON WHICH THE APPEAL IS TO BE BASED. IF YOU ARE A PERSON
WITH A DISABILITY WHO NEEDS AN ACCOMMODATION IN ORDER TO PARTICIPATE IN THIS
MEETING YOU ARE ENTITLED TO THE PROVISION OF CERTAIN ASSISTANCE. PLEASE CONTACT
THE PELICAN BAY SERVICES DIVISION AT (239) 597-1749 OR VISIT
P ELICAN BAYS ERVICESD IVIS ION.N ET.
6/12/2014
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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TABLE OF CONTENTS
CLAM BAY NRPA MANAGEMENT PLAN EXECUTIVE SUMMARY
List of Figures: m
Acronym Key iv
1.0 Introduction 1
PURPOSE OF THE CLAM BAY NATURAL RESOURCE PROTECTION AREA MANAGEMENT PLAN 1
DEVELOPMENT OF THE CLAM BAY NRPA MANAGEMENT PLAN 1
ROLE OF THE PELICAN BAY SERVICES DIVISION 3
2.0 Overview of the Clam Bay NRPA 5
DESCRIPTION OF THE SYSTEM 5
ADJACENT COMMUNITIES 7
HISTORICAL OVERVIEW 8
MANGROVE DIE-OFF AND RESTORATION 11
3.0 Physical and Natural Resource Description and Assessment 12
SOILS 12
NATURAL COMMUNITIES 12
INVASIVE,NON-NATIVE AND PROBLEM SPECIES 22
LISTED SPECIES 23
OTHER SPECIES 24
HYDROLOGY 25
INLET DYNAMICS 27
FRESHWATER COMPONENT 28
WATER QUALITY 30
ARCHAEOLOGICAL RESOURCES 33
RECREATIONAL USE 33
4.0 Management Plan Goal and Supporting Objectives 35
OBJECTIVE 1-MAINTAIN AND PROTECT THE NATIVE FLORAL AND FAUNAL COMMUNITIES WITHIN THE CLAM BAY NRPA 36
OBJECTIVE 2-ENSURE THE ESTUARY HAS ADEQUATE TIDAL AND FRESHWATER FLOWS TO MAINTAIN ECOLOGICAL HEALTH WITHIN THE CLAM BAY
NRPA 37
OBJECTIVE 3-MONITOR AND MAINTAIN WATER QUALITY WITHIN THE CLAM BAY NRPA 37
OBJECTIVE 4-MONITOR ARCHAEOLOGICAL SITES WITHIN THE CLAM BAY N RPA 38
OBJECTIVE 5-ENSURE RECREATIONAL ACTIVITIES ARE ENVIRONMENTALLY COMPATIBLE WITHIN THE CLAM BAY NRPA 38
5.0 Clam Pass Dredging 39
A. DREDGING POLICY 39
B. DREDGING CRITERIA 39
1. BAY TIDE RANGE 39
2. CROSS SECTION OF FLOW AREA AND VOLUME OF SHOALED MATERIAL 40
3. INLET CHANNEL LENGTH 41
4. EBB SHOAL 41
C. DREDGING CONSTRUCTION 42
1. TYPICAL CROSS-SECTIONS FOR DREDGING 42
6.0 Authorized Construction Activities 46
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LIST OF PERMITS FOR WORK UNDERTAKEN TO DATE AND RELEVANT LEGAL FRAMEWORK 46
7.0 Clam Bay NRPA Management Plan Amendments 47
Clam Bay NRPA Management Plan Stakeholders Groups and Review Agencies 48
Clam Bay NRPA Management Plan Bibliography 50
Appendix 1—Timeline of important events within the Clam Bay NRPA and a List of Permits for Work Undertaken in
and Around the Clam Bay NRPA 1
Appendix 2—A Recent History of Mangrove Management in Clam Bay 2
Appendix 3—Recent History of Seagrass Presence in Clam Bay 3
Appendix 4—Natural Resources,Communities,and Species Found within the Clam Bay NRPA 4
Appendix 5-Clam Pass Maintenance Dredging Design Critera 5
Exhibits 6
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
CLAM BAY NRPA MANAGEMENT PLAN EXECUTIVE SUMMARY
The Clam Bay Natural Resource Protection Area(NRPA) is a 570-acre estuarine system consisting of
sandy beaches, Clam Pass, shallow bays, tidal creeks or tributaries, seagrass beds, and mangrove
forests on the west coast of Collier County in Southwest Florida. The NRPA includes three primary
bays, Outer Clam Bay(southernmost), Inner Clam Bay(central), and Upper Clam Bay(northernmost),
connected by a series of tidal creeks and connected to the Gulf of Mexico by Clam Pass.
The preparation and implementation of the Clam Bay NRPA Management Plan has been undertaken
by the Pelican Bay Services Division at the direction of the Collier County Board of County
Commissioners. The Management Plan will provide guidance for future management activities within
the NRPA, building on the successes of the 1998 Restoration and Management Plan, by outlining the
goal and objectives designed to protect, maintain, and monitor the natural resources within the NRPA
and foster responsible stewardship going forward. The Management Plan provides an overview of the
natural resources and processes within the NRPA along with a summary of the surrounding
development and a brief historical perspective of past events and activities which have affected it.
Coordination with community members and stakeholders has been balanced with anticipated
administrative and financial resources to develop the following goal and supporting objectives for this
Management Plan.
Goal: to establish the basis for management activities that will be undertaken to protect the health of
the Clam Bay NRPA estuary.
Objectives to support this goal include:
1. Maintain and protect the native floral and faunal communities within the Clam Bay NRPA
2. Ensure the estuary has adequate tidal and freshwater flows to maintain ecological health
within the Clam Bay NRPA
3. Monitor and maintain water quality within the Clam Bay NRPA
4. Monitor archaeological sites within the Clam Bay NRPA
5. Ensure recreational activities are environmentally compatible within the Clam Bay NRPA
In support of these objectives, periodic monitoring of the terrestrial and benthic habitats will be
conducted. Encroachments into the NRPA by exotic and nuisance vegetation will be documented and
scheduled for removal or control. Observations and documentation of the wildlife utilization within the
NRPA will be documented periodically. Monitoring of water quality and freshwater inputs into the
NRPA will be continued. Archaeological resources within the NRPA will be periodically monitored
and any degradation will be reported to the State Historic Preservation Offices. Educational
opportunities will be explored and acted upon to promote environmentally compatible recreational uses
within the NRPA. Irresponsible or environmentally damaging activities will be documented and where
appropriate, reported to the proper authorities.
Regular monitoring of Clam Pass will be conducted to track the stability of the inlet. The Management
Plan outlines the following parameters that will be investigated and used by the consulting engineers
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
and the PBSD Board to make a recommendation of when and where dredging might be undertaken to
maintain the tidal exchange necessary for the long-term health of the estuary.
Description
Bay Tide Range Ratio ratio comparison of the interior and Gulf tidal ranges
Cross Sectional Area area in different locations of the Pass through which water can flow
Volume of Shoaled Material quantity of sand and sediments within channel that can restrict flow
Inlet Channel Length distance water must flow through the beach and ebb shoal areas
Ebb Shoal distance from shore to the outer ebb shoal limits
The Management Plan also includes typical dredging templates for the three sections of Clam Pass and
flood shoal that show the cross sectional areas that could be dredged in any event.
All monitoring,investigative, and management activities from the preceding year will be compiled into
an annual report and summarized in an annual presentation to the PBSD Board. Comparisons to
historic data will be done where appropriate to track trends and make determinations as to whether
additional interventions are needed to maintain the estuary health. Biological monitoring, water
quality monitoring, Pass bathymetry and status investigations, and any other activities conducted or
data collected during the preceding year will be documented in the annual report.
The Management Plan will also be used to support permit applications that may be required for
management activities in support of the Goal and Objectives. It provides the information needed for
assurances to the permit review agencies regarding what resources are present (or may be present) in
the system, why management actions are being undertaken, and how minimization of impacts to the
natural resources in the system will be achieved. The document also allows for changes to the plan
should new information or management techniques come to light that would be of benefit to the Clam
Bay NRPA.
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List of Figures:
- Figure 1—Approximate extent of Clam Bay NRPA Boundary—Page 6
- Figure 2—Historic Aerials—Page 9-10
- Figure 3—Soils map of the Clam Bay NRPA—Page 12
- Figure 4—Beach Habitat within the NRPA Boundary—Page 13
- Figure 5—Coastal Scrub habitat within the NRPA Boundary—Page 14
- Figure 6—Cabbage Palm Hammock habitat within the NRPA Boundary—Page 15
- Figure 7—Open Water habitat within the NRPA Boundary—Page 15
- Figure 8—Mangrove habitat within the NRPA Boundary—Page 16
- Figure 9—Salt Marsh habitat within the NRPA Boundary—Page 18
- Figure 10—Tidal Flat habitat within the NRPA Boundary—Page 18
- Figure 11—Seagrass habitat within the NRPA Boundary—Page 19
- Figure 12—Oyster locations within the NRPA Boundary—Page 20
- Figure 13—Exhibit from Conservancy of Southwest Florida report—Page 21
- Figure 14—Hardbottom Community offshore of the NRPA Boundary—Page 22
- Figure 15—Ebb and Flood Shoals—Page 27
- Figure 16—Approximate locations of Drainage Basins within the Pelican Bay—Page 29
- Figure 17—Water Quality monitoring locations within the NRPA Boundary—Page 31
- Figure 18—Sections A,B,and C—page 40
- Figure 19—Typical maintenance dredging cross-section—Inlet Channel—Section A—Page 43
- Figure 20—Typical maintenance dredging cross-section—Seaward Flood Shoal—Section B—Page 44
- Figure 21—Typical maintenance dredging cross-section—Bayside Flood Shoal—Section C—Page 45
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Ver. 6.2
Acronym Key
BCC Collier County Board of County Commissioners
CBRMP Clam Bay Restoration and Management Plan
CBRS Coastal Barrier Resources System
DA Department of Army
DHR Division of Historical Resources
DNR Department of Natural Resources
ESA Endangered Species Act
FDEP Florida Department of Environmental Protection
FDER Florida Department of Environmental Regulations
FLEPPC Florida Exotic Pest Plan Council
FLUCFCS Florida Land Use, Cover, and Forms Classification System
FSU Florida State University
FWC Florida Fish and Wildlife Conservation Commission
FWS Fish and Wildlife Service
LIDAR Light Detecting and Ranging
MGD Millions of Gallons/Day
MSTBU Municipal Services Taxing Benefit Unit
NMFS National Marine Fisheries Service
NOAA National Oceanic and Atmospheric Administration
NRCS National Resource Conservation Services
NRPA Natural Resource Protection Area
PBID Pelican Bay Improvement District
PBSD Pelican Bay Services Division
PUD Planned Unit Development
ST Sensitive Treatment
TDS Total Dissolved Solids
TMDL Total Maximum Daily Load
USACE U.S.Army Corps of Engineers
USDA United States Department of Agriculture
USFWS U.S.Fish and Wildlife Service
WBID Water Body Identification
WCI Westinghouse Communities Inc.
iv
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1.0 Introduction
Purpose of the Clam Bay Natural Resource Protection Area Management Plan
The purpose of this management plan is to provide guidance and direction for the protection,
preservation, and maintenance of the Clam Bay Natural Resource Protection Area(NRPA). This plan
will form the basis by which future management decisions can be made by identifying the appropriate
techniques necessary to achieve long-term sustainability for the natural resources and their uses within
the Clam Bay NRPA.
This plan, in addition to providing a brief historical perspective of activities undertaken within this
system,will identify the management goal and objectives; allow for development of methods to
achieve the goal and objectives; and summarize implementation, assessment, and evaluation strategies
that strive to balance resource protection with recreational use. While the 1998 Clam Bay Restoration
and Management Plan(1998 Management Plan)primarily focused on mangrove health and recovery,
this plan will address all floral and faunal components of the NRPA. The plan will draw from the 1998
Management Plan,input from multiple interested stakeholders, and historical biological,hydrological,
and physical reports to outline the goal and objectives for future management of the ecosystems
throughout Clam Bay.
The 2014 Clam Bay NRPA Management Plan(Management Plan)and any subsequent revisions
recommended by the Pelican Bay Services Division(PBSD) shall be submitted to the Collier County
Board of County Commissioners(BCC) for approval. Once approved by the BCC and relevant
regulatory agencies,this Management Plan, or future amended plans,will supersede all others and will
serve as the primary guidance tool for future permitting and other management activities necessary to
protect,preserve,maintain, and monitor resources within the system.
Development of the Clam Bay NRPA Management Plan
Turrell,Hall&Associates,Inc. served as the principal consultant for the Management Plan. This
consultant firm has a long history of work in the Clam Bay NRPA and was primarily responsible for
the implementation of the 1998 Management Plan that resulted in the successful restoration of Clam
Bay's mangrove forest. The coastal engineering firm of Humiston&Moore, Inc.provided input and
monitoring data for the 2014 Management Plan relative to Clam Pass and the dredging activities and
design criteria.
The PBSD Clam Bay Committee consists of members of the PBSD Board,which is an advisory board
to Collier County's Board of County Commissioners. The Clam Bay Committee met regularly in 2013
and 2014 and provided input and direction to the consultants. Additional regular input was provided
by representatives of several stakeholder organizations,including the Mangrove Action Group, as well
as several interested Pelican Bay residents. All Committee and Board meetings were properly noticed,
open to the public, and allowed audience participation. Input was also solicited via notices to more
than 30 area businesses, government officials and employees, condominium associations, and
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CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
individuals who regularly use Clam Bay. These representatives were invited to participate in two
meetings held in the spring of 2013. Some have attended and provided comments at the periodic
meetings of the PBSD Clam Bay Committee where drafts of the Management Plan have been
discussed. Stakeholders were also notified in April 2014 that a draft of the Management Plan was
available on the PBSD's website, and they were invited to send their comments to the PBSD's office
and/or attend a workshop about the Clam Bay NRPA Management Plan on May 14,2014. A list of
these area people/organizations is included with this Management Plan(pages 48 and 49).
Pelican Bay Services Division Turrell,Hall&Associates, Inc.
Chairman Tim Hall—Project Manager
801 Laurel Oak Drive, Suite 302 Arielle Poulos—Project Biologist
Naples,Florida 34108 3584 Exchange Avenue
(239)597-1749 Naples,Florida 34104
(239) 643-0166
Humiston&Moore Engineers
Brett Moore—Project Manager
Mohamed Dabees—Project Engineer
5679 Strand Court
Naples,Florida 34110
(239) 594-2021
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CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
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Ver. 6.2
Role of the Pelican Bay Services Division
In order for the management and maintenance of the Clam Bay NRPA to be successful, coordination
between a myriad of local, state, and federal agencies and interested citizens groups is required. The
PBSD has undertaken that role for most of the past fifteen years.
The Pelican Bay Municipal Services Taxing and Benefit Unit(MSTBU) is a dependent special district
that was formed pursuant to Chapter 125 of the Florida Statutes and was formally enabled by the BCC
pursuant to Ordinance numbers 90-111 and 91-22. These ordinances were replaced in 2002 by
Ordinance 2002-27 which further clarified the role of the MSTBU and the PBSD Board. This MSTBU
was created to, among other things,provide for the maintenance of conservation and preserve areas
within Pelican Bay.
This responsibility was undertaken diligently from 1998 to 2009 and resulted in the implementation of
the previous 1998 Management Plan and the recovery of the mangrove die-off areas. Per action by the
BCC,the responsibility for many of the monitoring and maintenance activities associated with Clam
Bay was given to Collier County's Coastal Zone Management Department from 2009 to 2012. In
2013,the BCC returned responsibility for the monitoring and maintenance of the system to the PBSD
via Ordinances 2013-19 and 2013-61. It is under the PBSD's direction that this current management
plan has been written.
While the MSTBU is a dependent special taxing and benefit district,the PBSD is an arm of Collier
County government and makes recommendations to the BCC. The PBSD implements its defined
responsibilities within the Pelican Bay community, sets its own budget and agenda, and regularly
submits them to the BCC for approval. The BCC has commonly approved the Clam Bay management
activities and authorized the development of this Management Plan. The PBSD's effective working
relationship with the BCC is expected to continue as the PBSD serves as the official manager of the
2014 Management Plan which is consistent with Ordinances 90-111, 2002-27, 2013-19 and 2013-61 of
Collier County.
The PBSD will direct the Management Plan and has the responsibility for its implementation and
operation over time. As such,the PBSD will plan and implement defined management activities with
BCC approval whose purpose will be to protect,preserve,maintain, and monitor the natural
communities and ecological integrity of the Clam Bay NRPA.
The PBSD has several attributes which make it a logical guiding force in the management and
maintenance of Clam Bay. The PBSD:
• is located within the Clam Bay drainage basin;
• has an advisory board made up of residential and business members within Pelican Bay;
• garners fiscal support for community projects, including Clam Bay NRPA activities,collected
from local special assessments (non ad valorem taxes)of the residents and business members
within Pelican Bay;
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CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
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May 30, 2014
Ver. 6.2
• is accessible to the public due to its local governing board and advertised public monthly
meetings; and
• has demonstrated a long-term commitment to the Clam Bay NRPA and a successful track
record regarding its preservation,restoration and maintenance over the past fifteen years.
These attributes give the PBSD the knowledge and expertise in matters of local concern and,in
particular, the problems, opportunities, and interests of local residents as they relate to the Clam Bay
ecosystem. Its relationship with the BCC gives it an additional level of access to technical expertise
and oversight that will be necessary to assure that the Management Plan, as contemplated in this
document, is fully implemented in the field.
As part of its responsibilities, the PBSD will assemble and distribute various technical reports and
assessments as required under the Management Plan, as well as coordinate with other public and
private groups interested in Clam Bay. The PBSD is organized for and designed to maintain both its
knowledge of the Clam Bay resources and to generate public support of the same. The PBSD will
insure that the general public, residents in Pelican Bay,the PBSD consultants, and representatives from
government agencies with jurisdiction over Clam Bay each have on-going involvement and input into
the Management Plan as appropriate.
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May 30, 2014
Ver. 6.2
2.0 Overview of the Clam Bay NRPA
Description of the System
The Clam Bay NRPA is a 570-acre estuarine system consisting of sandy beaches, Clam Pass, shallow
bays, tidal creeks or tributaries, seagrass beds, and mangrove forests on the west coast of Collier
County in Southwest Florida. The Clam Bay system is part of the Cocohatchee-Gordon River
Transition referred to by the Collier County Department of Natural Resources as Coastal Zone II. It is
one of the few remaining estuarine systems in the Cocohatchee-Gordon River Drainage System.
Historically the Clam Bay System was connected to Wiggins Pass to the north via a system of
mangrove swamps and shallow creeks with intermediate open water areas that were excavated and are
now known as Vanderbilt Lagoon(Collier County, 1994,Tropical Biolndustries, 1978). It is
recognized that the connection was marginal at best and while passable at times, it was not uniformly
and consistently navigable(Clam Bay Restoration and Management Plan, 1998). Connection to
Vanderbilt Lagoon ended in 1952 with the construction of Vanderbilt Beach Road.
Similarly, aerial photos of the Seagate Drive area taken prior to its construction show that Outer Clam
Bay was connected to the mangrove swamps to the south via shallow meandering creeks and
intermediate open waters leading to Doctors Pass. These creeks were only navigable by canoes and
small skiffs (Turrell, 2009). These swamps to the south were eventually excavated to become
Venetian and Moorings Bays. The connection to Outer Clam Bay ended in 1958 when Seagate Drive
was constructed.
Today,the Clam Bay NRPA includes three primary bays, Outer Clam Bay(southernmost), Inner Clam
Bay(central), and Upper Clam Bay(northernmost), connected by a series of tidal creeks and
connected to the Gulf of Mexico by Clam Pass. The community of Pelican Bay abuts the northern and
eastern edges of the system, while Seagate and Naples Cay communities abut the southern portion of
the system. This system is an important natural and recreational resource for local residents and
visitors.
The Clam Bay system was designated a Natural Resources Protection Area(NRPA)by Collier County
in 1995. The purpose of the NRPA designation is to protect endangered or potentially endangered
species and to identify large connected intact and relatively unfragmented habitats, which may be
important for listed species (Collier County, 1994). See the NRPA timeline(Appendix 1) later in this
report for more details on the NRPA history.
Clam Pass is a small, marginally stable inlet that has migrated north and south along the shore over the
years. Prior to dredging, average water depths of Clam Pass were-2.5' to -1.0', and its width ranged
from 30-50' (Collier County, 1994). The Pass remains the primary source of tidal exchange for the
Clam Bay system,but it is restricted by sediment deposits just inside the Pass and in the long
meandering tidal creeks surrounded by mangrove forests.
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t .111.". ,,t'',,' . .•.
Figure 1:Approximate extent of Clam Bay NRPA boundary.
NRPA Vital Statistics
Total acres: ApprColxa.m57B0ayacres
BeachBe a c h esPark:: AppArpopxr.Approx.
0. 30e
50 feacresfeet
Mangrove:aterA:pApprporxo.x4.2101a5acres
acres
Open Water:
a i
L ftude and Longitude
of Pass: N2362138,3'T1wl48S, Rng 25E, &
"w,Wp49s,81°4
Section, Township,Range: Sec. 32(WBID)8z37QRng9' 01"
25E
Water Body IdentificationSec. 4, 5, :, 8z 9,1
6
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Adjacent Communities
The Clam Bay system is bound on the north by Vanderbilt Beach Road and the Bay Colony portion of
the Pelican Bay development;to the south by Seagate Drive, and the Seagate and Naples Cay
developments;to the east by the Pelican Bay development; and to the west by the Gulf of Mexico and
the Strand neighborhood of Bay Colony that is within the Pelican Bay development.
Pelican Bay is predominately a residential community consisting of private single-family homes,
villas, and both high and low-rise condominium units. The community also includes a 27-hole golf
course, common areas with meeting rooms,tennis courts,beach park facilities, emergency services
facilities,and commercial areas with shopping and hotels. The 2,104-acre Planned Unit Development
(PUD)was approved in 1977 as a partnership between Collier Enterprises and Westinghouse
Communities(WCI). It was one of the first developments in Florida required to save fragile coastal
wetlands and associated ecosystems(Urban Land Institute, 1981). The development of Pelican Bay
had a limited impact on the wetlands themselves with approximately 94 acres, including about 78 acres
in the northwestern corner of the property,being developed. This left the majority of the mangrove
forest intact and preserved around the bays. As mitigation for these wetland impacts,the 570 acre
preserve area,including the 35 acre beach park,was donated to Collier County and eventually became
the NRPA which is in place today.
Development of Pelican Bay required a stormwater management system designed to spread runoff
along the eastern edge of the Clam Bay estuary. A four to six foot high and 2 %2 mile long berm
separates the developed portion of Pelican Bay from the estuary lying to the west of the development,
but numerous culverts through the berm discharge water to a swale system along the eastern perimeter
of Clam Bay. The eastern edge of Pelican Bay is about 12-14 feet above sea level at US 41, sloping in
an east-west direction to about 2 feet above sea level near the berm. Six drainage basins operate on a
gravity system to slowly move surface water into the receiving area of Clam Bay.
Naples Cay is a high rise development consisting of 8 multi-story condominium buildings. The
community also includes pools,tennis courts, approximately 33 acres of park and preserve areas, and
two canoe and kayak launching piers. Construction on the first building in Naples Cay started in the
late 1970's, and the last building was completed in 2002. Stormwater management is accomplished
through several internal detention areas before water flows into Outer Clam Bay.
The Seagate community is composed of about 80 single-family residences. The community was first
laid out in the 1950's and still has a few undeveloped lots. Because development of this community
occurred so early,there was no community-wide stormwater system. More recent improvements to the
road and utility systems have allowed for some dry retention and sewerage improvements to be put in
place. Many of the homes within Seagate were built with boat docks along the community's man-
made canals. Some homeowners keep motorized vessels at these docks. The 1995 Manatee Protection
Plan acknowledges that access and use of Clam Bay was limited due to the shallow nature of the bay
and ephemeral conditions. Vessels are generally shallow drafted, and their access is limited by the day
to day conditions of the Pass and connecting waterway.
7
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Clam Pass Park is a 35-acre County park providing beach access on the south side of Clam Pass. The
Park is wholly contained within the NRPA boundary. Access to the Park is via a boardwalk through
the mangroves from the parking lot at the very southern end of Pelican Bay. Operation and care of the
Park is done under the supervision of the Collier County Parks and Recreation Department. Through
an agreement between the County and the Waldorf Astoria Hotel,much of the day-to-day operation of
the park is managed by the hotel.
Historical Overview
Prior to development,the entire coastline of South Florida would have resembled the Clam Bay
ecosystem with meandering mangrove-lined shallow waterways buffering sandy barrier islands and
natural terrestrial communities. Unique within the heavily developed coastal communities of Collier
County,the Clam Bay estuarine system is a valuable resource for wildlife(particularly juvenile marine
species and birds) as well as residents and visitors to the area who enjoy the low-impact recreational
opportunities of the system.
Within the Clam Bay system, four Indian shell mounds have been identified and listed on the Florida
Master Site Inventory as Clam Bay Shell Ridge, Inner Clam Bay Shell Mound,Brackish Hammock
and Bayhead Camp (Hartwell, et al, 1994).
Historically, Clam Pass was a small part of a large system of relatively shallow waterways and
interconnecting wetland communities extending from Lee County to Doctor's Pass. Anecdotal
evidence suggests that canoes and shallow drafted skiffs were used within many of these
interconnected areas.
During the 1950's this system was isolated from adjacent mangrove lined creeks and bays by the
construction of Seagate Drive to the south and the construction of Vanderbilt Beach Road to the north
(see attached Exhibit, 1952 Aerial). The practical effect was to leave Clam Pass as Clam Bay's only
connection to the Gulf.
The Clam Pass opening has moved over its lifetime up and down the shoreline,influenced by major
storm events and by man's alteration of the tidal prism and drainage basin that feeds the Pass. The
shifting location of the Pass and its often tenuous connection to the Gulf is evident in the following
series of aerial photos of the Pass over the past 60 years. Because of these conditions,the Pass is
susceptible to outside events and can periodically close,which has happened at least six times in the
last 25 years,most recently in 2013.
8
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
x
'
I
t
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r
r
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,� �1. PASS
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: , I ; .
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.: 2004 ..
1994 -- �
� �.;
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
CLAM CLAM
x
PASS 'ASS
2012 =
Figure 2:Historic aerials of the location of Clam Pass
The health of the mangrove forest is directly related to the connection at Clam Pass. The exchange of
seawater between Clam Pass and the Gulf is critical to the ability of the estuary to export organic
matter, as well as to help regulate excess salt and freshwater. It also supplies oxygen rich water from
the Gulf and keeps metabolic wastes from accumulating in the sediment, as discussed in more detail
later in this Management Plan.
The system is a mixture of mangrove-lined tidal creeks,mangrove forests, shallow bays and tidal
passes, seagrass beds,tidal flats, sandy beaches, and brackish interior wetlands. It consists of
approximately 420 acres of mangroves and some 115 acres of shallow, open water bays, as well as a
35-acre beachfront parcel(Clam Pass Beach Park) and approximately 1.5 miles of sandy beach.
A man-made water management berm now divides natural and developed portions where historically
mangrove forest would have transitioned gradually into the mesic coastal hammocks and upland pine
scrubs that made up the now developed portions of the Pelican Bay community.
A brief overview of habitat types, their key characteristics and value is provided in the Physical and
Natural Resource Description Section(Appendix 4)of this Management Plan.
With the development of the Collier County coastline,the Clam Bay NRPA has been protected as a
managed natural system that preserves the essential features and ecological function of a mangrove
estuary. The historical and natural events that have affected the Clam Bay system in recent times,
along with governmental actions, scientific studies and management responses, are shown in timelines
in Appendix 1. These depict the evolution of management activities in Clam Bay and provide the
context for the management goal and objectives presented in this Management Plan.
10
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Mangrove Die-off and Restoration
The first mention of stressed or dying mangroves within the Clam Bay NRPA came from the 1978
Tropical Biolndustries and Gee and Jensen report titled Carbon Flows in Portions of the Clam Pass
Estuarine System, Collier County, Florida. Reports of stressed or dying mangroves continued through
the 1980's and 90's. In 1995, a large area of dead and dying mangroves was documented
encompassing approximately 42 acres adjacent to Upper Clam Bay(Turrell, 1995). By 1999,this area
had expanded to approximately 50 acres (Turrell, 2000).
The Clam Bay Restoration and Management Plan(CBRMP)was finalized in 1998 to address the
mangrove die-off. The major objective of the plan was to restore the dead mangrove area through
improvements to tidal flushing capabilities of the system, including enhancements to tidal flow into
and out of the mangrove forest areas. This was accomplished through the dredging of Clam Pass and
portions of the interior channels within the system, removing impounded water from the die-off areas
and the construction of a network of hand-dug flushing channels throughout the original die-off area
and a few other areas exhibiting stress.
In the fifteen years following the implementation of the CBRMP the mangrove forest has undergone a
substantial recovery with over 90% of the original die-off area re-vegetated with new mangrove
growth.
For a timeline of important events within the Clam Bay System, see Appendix 1.
11
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
3.0 Physical and Natural Resource Description and Assessment
The goal and objectives of this Management Plan aim to manage and preserve each of the resources
that make up the Clam Bay NRPA as a whole. The objectives of the Management Plan focus on
natural communities,tidal and freshwater flows,water quality, archeological resources and
recreational uses, all discussed further in this section. There are many additional factors that come
together to create the habitats and support the resources that make up the Clam Bay NRPA. These
additional factors are discussed further in Appendix 4.
Soils
Based on the National Resource Conservation Service (NRCS)"Soil Survey of Collier County Area,
Florida" (MRCS, 1998)there are 2 different soil types (soil map units)present within the NRPA
boundary: frequently flooded Durbin and Wulfert muck; and Canaveral Beaches Complex. These
mapping units named for soil series represent the dominant undisturbed soils in the landscape that
existed predevelopment. The unit descriptions do not recognize or appropriately interpret the
drastically disturbed nature of urban landscapes created after the soil survey was completed. For
information regarding soils specific to the Clam Bay NRPA, see Appendix 4.
fri r-2 ) • • y;j-. n'w 1, r'. :1� '
X ,) ter ".,,,.1°`:;44
;h:., i,Ga r.„:4,‘,-..- r� n ,/ .-.t
sem e.`f�.47." r .�.., ,.cC,,_�� _ .1' ,4p 4i f #„, :iv,
`�1.I�}:::-,,, T,1
-:,
i.R V` . . v^ws: . '.tir`�. , FKe"'t4v w` A.,.rft.0 Y `, all{ -- C`s .l.
. �d .:.-,\.$.'444.,,,1%idr w ,Lr icil '\ x-S ... < /', -'..�`___ t( 4,-
IOPPg
4.111
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r 7i tilt° I., -
I 140
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.L 1 J ..♦ -r -rte"'
_
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:% _1 1VG
U
Figure 3:Soils map of Clam Bay NRPA
Natural Communities
In this Section, a natural community refers to the mix of plant and animal species that form the natural
basis of the Clam Bay NRPA. A combination of factors,including geology, climate,topography, soils,
wind,waves, storms and anthropogenic influences, determines the specific types of plants found in any
given area(see Appendix 4 for more information). These plants are a major factor in what type of
animal species that may be present, including threatened and endangered species that may utilize the
Clam Bay NRPA(see Appendix 4 for more information). The Florida Department of Transportation's
12
CLAM BA YNRPA MANAGEMENT PLT)
Pelican Bay ServicesAN Division
May 30, 2014
Ver. 6.2
Land Use, Cover and Forms Classification System(FLUCFCS 1999)has been used to identify the
plant communities found within the Clam Bay NRPA. See the attached Exhibits for an overall
FLUCFCS map of the Clam Bay system and the existing monitoring plots within these habitats.
List of FLUCFCS Communities within the Clam Bay NRPA
FLUCFCS Community Description Upland or %of Clam Bay
Code Wetland NRPA
181 Swimming Beach Upland 5.95
186 Community Recreation Facilities Upland 0.40
322 Coastal Scrub Upland 3.97
428 Cabbage Palm Hammock Upland 0.45
510 and Interior Creeks and Bays (with and Wetland 23.16
540 without direct connection to Gulf or
Ocean)
612 Mangrove Swamp Wetland 64.60
642 Saltwater Marsh Wetland 0.04
651 Tidal Flat Wetland 1.43
911 Seagrasses** Wetland 0.84**
**included in the Bays (541)category
Several other components of the Clam Bay NRPA ecosystem are also addressed in Appendix 4. These
components include offshore hardbottom, oyster, and other benthic faunal communities that are not
specifically addressed in the FLUCFCS classification system. Additional historical information on the
natural communities within Clam Bay,the mangrove, and seagrass habitats is also included as
appendices to the Management Plan.
FLUCFCS Code 181-Swimming Beach q,
S Y 33 � r�.1 * 1', y �`A[g, sem` ���4 •��� � Ly.� ')i..-'4 ^ S l'.9-"N:-.... ..�
f d kr `itif . Z.lA I.441 /^+..i /t' -t l 9 {�5�,,,'��'Y`�jpi `. tc. ,.`,:'h',„, td'n .,_, 1.' 'q.J lt� kz tr d -�wi� s `� C'yW '�1 ''�'+ '4.yt t ,;p!.
' ` K� J Z j r� _. ?^r 4 lip 4. }(ti‘-S t ,l i j'S� k 9 ♦rC;d j,r :.
y.f .. ;,,74,..1 ,i1A 5 >F q $� ;° -d 3 ,? F-, tc ,, ',e ,,g lit., , rlls-- ,'lam'• ti
r'
°,g,' „,- ,,, ti,ye , r>� e Tat lift y� '" Y
,y, :Alitl. 'i y fir' -.w {rl t .t i Y..`-rY.irt F �y F n r, ,..tl� .1LY irk
S wK .y,i+ ➢5� ,44. 15"11' "II;'' ':4..' �• ! ':,' $Ja A r i,+i.""y 4'it%^ nY4 l
•J 4;�.
•
`, '� e- ,v.,,,,,
4m^'w141.4-1-L.,:-
" F` ` Y:'''.-+.:
" V �.s re S4 -' s • ,A'4'`V..,I..`
t a�t�� ' " •k 4.? 1';
4 Pains r, ; {
Figure 4:Beach habitat within the NRPA Boundary
13
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
There is approximately 8,675 linear feet of beach within the Clam Bay NRPA in three distinct
segments. Contiguous beach habitat extends from the NRPA habitat both north and south along the
coast. Shorebirds feed on marine invertebrates, such as coquina clams and mole crabs, at the water's
edge, and beaches are crucially important habitat for nesting sea turtles.
This particular habitat has been monitored periodically in terms of width as part of the Collier County
Beach renourishment program though no conclusive statements can be made about the floral or faunal
details of the ecotone over the years. Large scale generalizations based on the annual aerial
photographs can be made that the overall size, composition, and health of the habitat have remained
relatively stable, and with the exception of the areas immediately adjacent to the Pass, are mostly
unaffected by the status of the Pass.
Management concerns for the swimming beach are loss of beach area due to natural erosive processes
and recreational over-use of the resource.
FLUCFCS Code 322—Coastal Scrub
41
ir.M.F473-W14:51',;fi Tat:47,i fu,;for---7,1i7:4`7:;;Cragf7574:10441W 4r;:::-; !trItTlftive,t,
'` rJ & " h V rt S�.Vs.) p m7'+rpyt "i !-. `t ..Y is 1� .. �'.t:`v,.,
'� '`.�,,+
,., k '''fo,,_
�. 1 _1 S .rt• t'�q 1 , .,.', 7;',z. i` •n \ ''Y t ��1)'' 0. ''(rtet C4`/4,.� :
..may... fi� .SF,It �+ • :.,..7 ' aJ' 9 R f ,, ,l Ir
j , ,k`.a yv � ... ryasr `I�E� tem r a
, -"t-,,., ,-V-1-7,477,,i-fri7W4Z1%,VP* -3% '.'42:,,t _
0J.hyke-,-,,6144,,,,.0Tirt----.,,_,,,,,,. ...._ '-1,, ..,-,7..-i,, ,,,,, .,,,.;::,:y-,--- , - -- _, . .
,...-j,----„, - k#1r 1,3,4-,,---. j., •,
--- 322 -
Figure 5: Coastal Scrub habitat within the NRPA Boundary
Landward of the frontal(beach)zone area is the back dune zone(also often called the coastal shrub or
scrub zone). This portion of the dune is more stable,has greater organic matter, and supports less salt
tolerant grasses and shrubs as well as some trees. Coastal scrub is represented by a conglomeration of
coastal species generally found in a narrow band between an estuary and the beach.
Many of the woody species found in coastal scrub are low growing due to low nutrient and droughty
conditions of sandy soils. High winds and salt spray often prune the terminal buds of the trees and
shrubs growing on the dunes and result in salt-pruned,windswept canopies.
Species common in the coastal scrub zone of the Clam Bay system include: seagrape (Coccoloba
uvifera), cabbage palm(Sabal palmetto),buttonwood(Conocarpus erectus) and Spanish bayonet
(Yucca aloifolia). This is an important habitat as it helps anchor the back dune sands and provides
habitat for several listed plant and animal species including the gopher tortoise(Gopherus
polyphemus).
14
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
The primary management issues of concern in the coastal scrub are gopher tortoise habitat
management and exotic vegetation control.
FLUCFCS Code 428—Cabbage Palm Hammock
�, cd� i s-h'R'1:',760-.„ tc,v .1,� Y 'r S #0,, r,3 — * " . 1 i;�.T -:-Ti:,,-1-7.4
a_ 1
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s.
+rlJ, j4 21Pr l' 17
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tr 7 . :143) irjp,.. t." "".•... f , ti� { {�, 1 N:-� �{
4 -iiii'::;
7 ,,',1:,, ti.s��'7 '�:5 s .4 11, 7 4' � .., ji ('�_.'' i.3-fi�`�C;;.r�,ei!.. + 1..2i'•w�4 t .'FFr,j�`�''l ,•
,, cy�. A
•, . 4
.. , 1
- b
Figure 6:Cabbage Palm Hammock habitat within the NRPA Boundary
This forested zone is composed of dune vegetation and is located inland of the coastal scrub-farthest
from the Gulf of Mexico. The Cabbage Palm Hammock habitat consists primarily of cabbage palms
(Sabal palmetto) and is found in sandy soils. In the Clam Bay NRPA it is generally found in pockets
located between the mangrove forest and the coastal scrub zone or beach areas.
The primary management issues for this habitat are exotic control and preventing destructive visitor
access.
FLUCFCS Code 510 and 540—Interconnecting Creeks and Bay(with and without connection to
the Gulf)
.n c - �c• a� s'r sf{ t — L ` .a.-r -� ,1.1":41-:::',
Q t-y VI-,. O r . ^ 1r�F75� . rri � .
•,,_... 1«r ' < y/<� ;.:9": ' k I � 71i tgtf- Zr # fS o-7yia., 144 4: 'q`,j II* r . f% , s „y �irgun7`,.., .-8.4.-.•• ' -t g. .' {r'*7A "SE•, Q- , S6Y1 '¢ 4 ' �13� „i_.,..4.,...-..; 1 .. rf 1.11-5.17.,-.,-, ;- 0� -A V.1-'74'
y , =r 1` .`1 _. 7, rra rI ,,,,,,A9',. i5 •;1. 10= 1 ,yG, r = :"y , ll _ .S✓ a
�.�{
•1�Y.. y} j�y
'4�T, f w ., . . , -.•�,4-. - awe X14 Pi[ _ lr. k
540 — 54
Figure 7:Open Water habitat within NRPA Boundary
15
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
The Clam Bay NRPA contains the three larger bays associated with Clam Pass(Outer, Inner, and
Upper) as well as the interconnecting shallow creeks and small open water areas. These bays and
interconnections serve as the life blood of the estuary.
These open water habitats serve as the basis for many other communities. Seagrass beds, oyster bars,
clam beds, and other benthic communities can all be supported to varying degrees with the open waters
of the bays and interconnecting creeks.
Tidal creeks are passageways for fish and marine invertebrates between waters of the Gulf and the
protected embayments of Clam Bay. Manatees, dolphins, and turtles may also use the Pass. Scouring
action of the fast flowing tide generally prevents colonization of seagrasses and other benthic flora.
Management concerns related to the bays and associated creeks include maintaining sufficient flow
through them to accomplish flushing needs of the system, stabilization of the Pass without harming
other components of the NRPA, and educating recreational users of the NRPA of the need to protect
the shallow water habitats and the communities located therein.
FLUCFCS Code 612—Mangrove Swamps (Forest) 3
r ��-s�rti� .p--� r ti� /�, 7 .�" �{s4� .aa'� F'4'' ,�#@ 7' • '� C��`' �i;,�i'4
rasp #_ € i�' _ 4+!�k+t, � ''),.. --_`11,1z11:,31:44.:,t • a, ='.,, ,
N.. ,-,..41V '-;. ,0, 65 ' re ,t r t, -4 :41 g s � f1 tI'
• :-
r 4-4 6 404,,, 1
.p - --
Figure 8:Mangrove habitat within the NRPA Boundary
Mangroves are salt tolerant trees that grow in tidal areas of the tropics and are legally protected for
their ecological value and function as:
• Providing habitat for marine,terrestrial, and avian wildlife.
• Protecting coastal areas from storm surges and coastal erosion.
• Improving water quality by acting as a natural filter for land-based freshwater run-off.
• Forming the basis of a highly productive estuarine food chain which includes many
commercially valuable species.
• Enhancing the atmosphere by absorbing carbon dioxide and reducing greenhouse gases.
Approximately 65%of the Clam Bay NRPA is composed of the three most common mangrove species
in Florida,namely red mangroves(Rhizophora mangle),black mangroves(Avicennia germinans), and
16
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
white mangroves (Laguncularia racemosa). All three species have special biological adaptations to
cope with salt and unstable,mucky, low oxygen soils that result from the tidal,hence continually
waterlogged, environment. The dominance of mangroves in tidal areas is a function of these
adaptations and their ability to out compete other wetland plants. Tidal flushing allows nutrients to be
distributed within the forest and provides for the transportation of dead leaves, twigs, etc. As this
material decays, it becomes food for marine life. It is this mangrove detritus which is consumed by the
many organisms at the base of the food chain which in turn creates the next level of the food chain
necessary to support the fish populations that characterize the mangrove community.
The Clam Bay mangrove community is composed of both riverine(along the creeks) and basin forest
components.
Riverine (Creeks)Mangroves
On the waterward edges of small islands and the tidal creeks,passes and estuarine waterways that
make up the Clam Bay system, a fringe of red mangroves will be found growing up to 25 feet in
height. This zone can be just one or two trees in depth or extend landward for some distance,
depending on topography. The habitat provided by the prop roots of these red mangroves is of great
importance to many fish and other aquatic organisms.
Forests
The majority of the Clam Bay mangrove habitat is low-lying basin forest where the dominant
mangrove species varies between red,white, and black through the forest habitat. This forest
community was the habitat affected by the mangrove die-off. The hand dug flushing channels were
constructed throughout this community to increase the flushing capacity through tidal inundation.
Special attention has been given to the mangrove community in the past because of the die-off which
occurred between 1991 and 1997 (though stress in the community was documented as far back as the
late 1970's). The die-off affected black and red mangroves initially but eventually ended up
encompassing some white mangroves as well. More details on the recent history of the mangrove
management are provided in Appendix 2 included with this plan.
Management concerns within the mangrove habitat include ensuring adequate tidal flushing and
protection from exotic vegetation or pest infestations.
17
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
FLUCFCS Code 642–Salt Marsh
',,+t 'w + . s . ,14 - 4 C �.q Y•
rUirSr..-W:111,47;'',
likr .k 4-. 1 '1M1It' q t.14 +i
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
scavenge detritus or, in the case of many bivalve mollusks, extend siphons at high tide and filter vast
quantities of water. Birds, such as a variety of herons,ibis, egrets, and spoonbills pick through the
sediment for the invertebrate food sources.
The dredging of the Pass associated with the 1998 Restoration and Management Plan resulted in an
increase of exposed tidal flats within the southern portion of the system. Increased tidal range
resulting from the dredging allowed more area to be periodically exposed during the tidal cycle. Some
of the area that had supported seagrasses prior to the dredging work were converted into the tidal flats
by the increased range and reduced phase lag.
Management concerns related to the tidal flats include the templates established for the dredging,the
resultant currents that could be expected as a result of dredging, and the frequency of disturbance.
FLUCFCS Code 911—Seagrass Beds
.s��.i 5 .f i�• 3 'yam t� 7 � as,.,-e[r f�,{�,► Y�{i�-� ni s,y-r.t•- .
f,$ .�J:'7•r i 4 1' y1. ,t,,,;, ,0*s� d✓�.�,5 727;;'` i, 7'ti:r� - �;y �4`,�K Gu t I
t ` ,i.a� r` d {?46�lY i .1 1 ,. �of � M1 y ki a�� '4O i i7-a ,,j
fj 1 7!.,.1,5V"-5,,,k' ry.+ 1 'ti +f�,y� 'l yoi7 4.{.ids q,.9f G <;,-;`AN �';It ‘ii!)
Ctif
� 4.n{ ,,1^,":,:V,,..1,;,::-. f� '� t� r'tYt r r {+. ter''" i
. 5r r.. ' r yy �1 i. .�� 21
7 ad
-v;w,! `-r° i a '• il`' r" `y'. ....:SIS a, • .
glFigure 11:Seagrass habitat within the NRPA Boundary
Several areas within the Clam Bay system host seagrass beds, specifically Outer Clam Bay and
waterways just inside Clam Pass(see attached Exhibts). Three species are commonly found in these
Clam Bay waters: the largest turtle grass (Thalassia testudinum)with flat strap shaped leaves, the
smaller shoal grass(Halodule beaudettei(flea wrightii))with narrow, flat blades and paddle grass
(Halophila decepiens)with the smallest,paddle shaped leaves. Shoal grass is by far the most common
though a small area of turtle grass has persisted since the 1998 dredging.Paddle grass is much more
ephemeral in nature, and diligence is required to be able to locate it during the time frames when it is
present.
Seagrass coverage in Clam Bay has varied over time but has always been found predominately in
Outer Clam Bay and the waterway between this bay and Clam Pass. A 1994 Collier County report
estimated seagrass coverage at approximately 10 acres. Pre-dredge surveys conducted in 1999
estimated coverage at about 5.13 acres. Annual monitoring of seagrass beds along the monitoring
transects has estimated coverage from a low of approximately 1.2 acres in 2003 to the current estimate
of 2.85 acres from the 2013 survey. It should be noted that the coverage estimates are taken from
19
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
along the survey transects only and do not account for other scattered grasses that may be located
elsewhere in the system.
Management concerns related to seagrasses include direct impacts due to recreational use and potential
dredging templates, turbidity and water quality concerns related to flushing(too much or too little)and
stormwater inputs, and algal infestations due to nutrient increases.
A history of the seagrass monitoring efforts in Clam Bay is included in the Appendix 3 attached to this
report.
Other Benthic Habitats
Oyster Bars
I
fin-. �\{y� J, r 3 - �{.t�,st— y,t+hs. :s �T a Tc-c--c-7-.fri 7.5111_" jy.,:t�W1J 3*, s '4''y'
tf - `'4i� i t � ' $ k, si�S ; +.a--"P�1.�� ti �' ?V"' �r :44:}-tti,41. Y+z¢Ft.`'S j
ti - p r t i ; � i .c ' 'r" 4.7.3: c.•c 4 t+ ..i. 9 7
S c k}" _ ..',' •' r 0`, a t,f k., 1 1 , Mfr t .1-17 rVasi`'t� tv�*
e7^• 5+f r ,.--...--,,e6-4 ,, ,-4:...-..,:--„.t`xt,. :i 4.i Y t Ari [rr +�� :s *t. Lil
..�
.1%.! .ms
4Y y
4 1_41
COX +a�' �ti � � S �'e` � `
'y ,_.,--,,p,- t I 4 x � l�
„ s
{ µ r , ::, . OXIMATE OYSTER LOCATI 1
Figure 12: Oyster locations within the NRPA boundary
Oysters(Croassostrea americana) are filter-feeding bivalves, which were once common within the
tidal creeks of Clam Bay(Humm and Rehm 1972). Deteriorating conditions in part related to closures
of Clam Pass are thought to have resulted in the disappearance of oyster bars in the system,though
some re-occurrence has been observed to the south of the Pass in the last few years during seagrass
transect monitoring. Oysters have been documented around the perimeter of Outer Clam Bay in past
years' monitoring efforts.
A 2011 benthic habitat assessment conducted by the Conservancy of Southwest Florida found living
oyster clusters in the upper reaches of Upper Clam Bay(a single cluster), in the tributary between
Outer and Inner Clam Bays (a single cluster), and throughout the shoreline of Outer Clam Bay.
Management concerns related to oyster growth are similar to the seagrass concerns,namely protection
from recreation users,water quality, and flushing.
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CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Other bivalve mollusks
In addition to oysters, the 2011 benthic habitat assessment conducted by the Conservancy of Southwest
Florida also found two other bivalves within the Clam Bay system. The pointed venus clam
(Anomalocardia auberiana)and the stout razor clam(Tagelus plebeius)were both observed. Turrell,
Hall &Associates,Inc. benthic surveys found several beds of southern hard clams (Mercenaria
campechiensis) also present in the system.
These mollusks are generally found within the shoal and tidal flat areas of the system and could be
susceptible to impact during dredging or other disturbance operations. Management concerns would
be protection from recreational users,water quality, flushing and dredging.
ry- .._-.44,...1.,verf,--0. yom., t,,,,,:,1 yowy.&,„40--.4, -, .eqYZ'A It.... 11:7"1.4,1,f":*:::':•••- *
W-tv.c1.1044r, v to.-t:.,.4441,-,Ari,,,,..„ ., ;,,r6r; .,__p,,,j, 1.04 ,
cc,.
� E � a + 1 �s�. _ h, °+c9� o-' &.4--....--e..,.` � 5?�'�� _ . t'4. y,.
S S E r ..S'C'' �e _ b i tFp��+
m N � 4r. .. Ei'" GiyaL'
y 8 ' *t6 rte^ _ t� ' Y
,e=-6
7 .i v R t- I1� •r,I iA,fy. /r te'' " isa`Z'n _l 9 y f`:4
a , l ,:' ,.N. hr::141"-• R .,�1: , ` e;. R'" likL ..--‘"--....-4,:,'' ' ^,tj"
7d
_ ... yam.. ...
x
a
*. ----
'1-r
Ill' . x!`s it ' `. .,t.,
•
_ .. ., ,
F
n =t
Figure 13:Exhibit from Conservancy of Southwest Florida Report
Tubiculous Polychaetes
Tubiculous polychaetes (tube worms) are typically the most abundant biological assemblage in Clam
Bay and are primarily associated with muddy and sandy substrates. Polychaetes,including worm tubes
and mud tubes, shell-encrusted polychaete tubes (Polychaeta) and trumpet worm(Pectinaria gouldi)
tubes, are a vital component of the estuarine food web,providing key linkages between primary
producers and higher trophic levels. Polychaetes create habitat and food for many organisms, such as
mollusks, fish and even sea turtles. These worms are usually filter or deposit feeders that keep the
substrate aerated and free of waste accumulation. Polychaetes tend to dominate Inner and Outer Clam
Bays,with lower occurrences in Upper Clam Bay, the Lower Tributary, and,to a lesser extent, the
Upper Tributary.
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CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Hardbottom Communities
t T"' •--.ler -,pr,n .u. . u, i' cm .� ''� -,T '4t-:''
il
_.0?,.
�� r`• '}.k r s� Y' --;41;- '.r �_ � s' - OUTER
�w CLAM BAY i
i1 s.�- ,t .- INNER -' " .. i..
�4, Y.k� UPPER. 1 CLAM BAY ' t }{
1
-,y ;'.Sy CLAMBAY • a��
a
...."."4
� r - - .CLAM
7.r, q 9 .�^�"`R� .iJM PASS r'2
ir‘f
GULF OF
MEXICO
Figure 14:Hardbottom Community off-shore of the NRPA boundary
Another important marine habitat marginally associated with the estuarine system is the hard bottom
reef community found just seaward of Clam Pass. In about 10-15 feet of water a variety of sponges,
stony corals, gorgonians, fish and associated invertebrates can be found within a system of rocks and
ledges. Outcroppings of similar habitat type occur along the length of Collier County and are a little
known resource of regional significance.
Collier County has mapped this resource through side scan sonar surveys in 2005 and 2009 as part of
its beach renourishment project. The information received from the County shows that the landward
edge of this habitat is located approximately 250 to 300 feet offshore from the Pass.
Management concerns related to this habitat include recreation use and potential turbidity impacts
resulting from dredging or other management activities within Clam Bay NRPA.
Invasive,Non-native and Problem Species
In an ecological context, an invasive species is one that is aggressive in growth and expansion of range
and tends to dominate other appropriate native species. Its establishment and dominance can cause
widespread harm to an ecological system by altering the species composition, susceptibility to fire and
hydrology of an area. Non-indigenous species(i.e.,non-native or exotic species) are those that have
been introduced purposefully or accidentally to an area outside their normal range. Category I species
are those that have been documented to drastically alter natural communities by displacing native
species. Category II plants have increased in abundance or frequency but have not yet altered Florida
plant communities to the extent shown by Category I species.
FLEPPC Category I plants observed within the Clam Bay NRPA boundary:
- Brazilian Pepper(Schinus terebinthifolius)
- Melaleuca(Melaleuca quinquenervia)
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CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
- Australian Pine (Casuarina equisetifolia)
- Beach Naupaka(Scaevola taccada)
- Earleaf Acacia(Acacia auriculiformis)
- Shoebutton Ardisia(Ardisia elliptica)
- Air Potato (Dioscorea bulbifera)
- Lantana(Lantana camara)
- Old World Climbing Fern(Lygodium microphyllum)
FLEPPC Category II plants observed within the Clam Bay NRPA boundary:
- Coconut Palm(Cocos nucifera)
- Wedelia(Sphagneticola trilobata)
- Oyster Plant(Tradescantia spathacea)
- Mahoe(Talipariti tiliaceum)
These species will be removed or reported to the responsible entity for removal.
Listed Species
State and federal wildlife agencies will review any proposed management activities within the Clam
Bay NRPA to determine if impacts to listed species will occur. While there are many listed species
(State and Federal)that utilize the Clam Bay NRPA,the six listed below have garnered the most
scrutiny as being vulnerable to impacts associated with Pass maintenance activities. These as well as
other listed species that do or potentially could utilize the NRPA are listed in Appendix 4.
Smalltooth Sawfish(Pristis pectinata)
A juvenile smalltooth sawfish was observed in 2008 in the connector creek between Inner and Outer
Clam Bays. Smalltooth sawfish are found in the tropical and subtropical Atlantic Ocean. In the
western Atlantic they have historically ranged from New York to Brazil, including the Gulf of Mexico
and Caribbean Sea. Habitat destruction and overfishing have succeeded in eradicating the smalltooth
sawfish from the majority of its former range. Consequently,it survives in small pockets throughout
its current range. The last remaining population in U.S.waters is off south Florida, a small remnant of
a population that once ranged from New York to Texas.
Mangrove Rivulus (Rivulus marmoratus)
This small fish has not been identified within the Clam Bay system in previous surveys or field work
but the mangrove habitat is appropriate, and they could be present in the upper reaches of the
mangrove forest. The mangrove rivulus is primarily a saltwater or brackish water species,with limited
occurrence in freshwater. Within the Everglades and along Florida's west coast,this fish occurs in
stagnant, seasonal ponds, and sloughs as well as in mosquito ditches within mangrove habitats. The
mangrove rivulus is able to survive in moist detritus without water for up to 60 days during periods of
drought, anaerobic, or high sulfide conditions.
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CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30, 2014
Ver. 6.2
Loggerhead Sea Turtle (Caretta caretta)
Loggerhead sea turtles have been documented nesting on beaches within the Clam Bay NRPA.
Loggerheads are circumglobal, occurring throughout the temperate and tropical regions of the Atlantic,
Pacific and Indian Oceans. They are the most abundant species of sea turtle found in the U.S. coastal
waters. In the Atlantic,the loggerhead turtles range extends from Newfoundland to as far south as
Argentina.
The loggerhead turtle was first listed under the Endangered Species Act as threatened throughout its
range on July 28, 1978. In September 2011,National Marine Fisheries Service(NMFS) and USFWS
listed 9 Distinct Population Segments of loggerhead sea turtles under the Endangered Species Act
(ESA). The population in the Northeast Atlantic Ocean Segment is listed as endangered. The agencies
are currently proposing Critical Habitat designations on several areas which contain a combination of
nearshore reproductive habitat,winter area,breeding areas, and migratory corridors. The Clam Bay
NRPA is contained within the LOGG-N-27 segment of this proposed critical habitat area.
Gopher Tortoise(Gopherus polyphemus)
Gopher tortoises and their burrows are found along the coastal strand portions of the Clam Bay NRPA.
The range of the tortoise includes southern portions of Alabama, South Carolina,Louisiana,
Mississippi, and Georgia as well as most of Florida.
Piping Plover(Charadrius melodus)
Piping plovers have been rarely sighted foraging or resting along the shoreline within the Clam Bay
NRPA boundaries. No nesting activities have been documented within the NRPA.
West Indian Manatee(Trichechus manatus)
Manatees have been sighted on numerous occasions within the Clam Bay NRPA boundaries.
Manatees can be found in shallow, slow moving rivers, estuaries, saltwater bays, canals, and coastal
areas particularly where seagrass beds or freshwater vegetation flourish. Manatees are a migratory
species. Within the U.S.,they are concentrated in Florida in the winter. In summer months, they can
be found as far west as Texas and as far north as Massachusetts,but summer sightings in Alabama,
Georgia and South Carolina are more common.
Other Species
A list of plant and animal species that has been observed within the Clam Bay NRPA and the adjacent
Pelican Bay development areas can be found in Appendix 4 of this Management Plan. These lists are
not all inclusive but represent a wide array of the species found within and adjacent to the Clam Bay
NRPA habitats.
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CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Hydrology
Hydrological regime,sometimes referred to as the surface water or surficial hydrology,in simple terms
describes the long term spatial variation in the water depths and period of inundation within a wetland
system. This is because the surficial hydrology has both horizontal and vertical components and
provides key ecological functions to the mangrove forest(Lewis,pers. comm.,2008).
With respect to the horizontal component, incoming water(both tidal and surface water run-off)into
an estuary brings with it nutrients,dissolved oxygen, and marginally lower salt concentrations.
Conversely, the outgoing water leaving a mangrove wetland(through tidal exchange)removes
metabolic waste products (e.g. carbon dioxide and toxic sulfides) and excess salt. The vertical
component refers to incoming water that percolates down into the sediment and root zone, and the
sediment drainage,on a falling tide which removes metabolic wastes and excess salt.
It is the inflow and outflow of sea water that is critical to the ability of the estuary to manage these two
ecological functions and as such dissipate salts, organic matter and freshwater. It follows that anything
that affects the system and alters the ability of the system to perform these functions,will, in most
instances, cause stress to the system and, at some point in time,result in the death of the system, or
portions of it.
Hydrologic studies indicate that the tidal flushing capacity of Clam Bay prior to the restoration
dredging was limited and almost insignificant in Upper Clam Bay. The preliminary hydrographic
assessment of the Clam Bay system prepared by Tackney&Associates, Inc. (August 1996)
demonstrated rather dramatically that there was a significant reduction in tidal range between the
middle boardwalk and Inner Clam Bay. Tackney described the flow in that area as"measurably
reduced"and"very inefficient". The connecting tidal creek between the Pass and Inner Clam Bay is
the key conduit for tidal input and outflow to the northern reaches of the Clam Bay system. Its
constriction and the ancillary constriction of tributaries connecting to it impact the quantity and quality
of the flushing that can occur in Inner and Upper Clam Bay.
Another key aspect of the surficial hydrology is the vertical location of the water level elevation
relative to the sediment elevation. Specifically,the mean low water(tide) elevation has to be
sufficiently lower than the sediment elevation in order for sediments to drain during low tide. A
persistent high surface water elevation stops sediment drainage and results in anoxic sediment and the
accumulation of toxic waste products. The absence of meaningful exchange was certainly a
contributor to the significant degradation of the mangrove system within Clam Bay. (Tackney 1996;
Lewis pers. comm.,2008).
In this context Tackney observed that even in the absence of rainfall,the average water surface
elevations for the inner and upper bays were higher than the average surface elevation for the Gulf.
Analysis of the tidal data indicated that average water surface elevations in the Inner and Upper Clam
Bays were both elevated above the average Gulf water surface elevation by approximately 0.2 feet.
This indicated that the tidal range in Inner and Upper Clam Bays was muted and that the system was
receiving significant additional water through runoff and restricted capacity to drain additional inflow.
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CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
In fact, during portions of the Tackney study no tidal fluctuation was noted in the Upper Clam Bay and
only marginal tidal effects were observed in Inner Clam Bay.
The reduced tidal ranges were also accompanied by relatively large phase lags. The phase lag is the
average time delay measured in hours and minutes between the occurrence of slack(high or low)water
in the Gulf of Mexico and the measurement stations. It is affected by both the distance between
measurement stations and the amount and quality of hydraulic resistance of the connecting channel.
The longer the distance and the higher the resistance,the more pronounced one would expect the phase
lag to be. In the upper bays,high and low waters generally occurred over three hours later than the
Gulf tides.
These conditions indicate that the tidal creeks connecting the interior bays are hydraulically very
inefficient. As a result,the upper bays are prone towards extended periods of flooding as a result of
freshwater runoff and the inability of the system to drain efficiently. During Tackney's field studies of
May 1996,rainfall of approximately 4 inches in three days was adequate to flood the Upper Clam Bay
above high tide levels and sustain this flooded condition for over two days. Accordingly,he concluded
that the creeks and bays that serve to connect the Inner and Upper Bays were significantly less efficient
in the ebb tide stage than they were in the flood stage. Studies undertaken by both Lewis
Environmental Services, Inc. and Turrell&Associates, Inc. would support this conclusion. (Turrell
1995).
Finally,an additional attribute of the system that is directly related to tidal prism and the quantity of
inflow and outflow is the question of inlet stability. Inlet stability refers to a tidal inlet's capacity to
adequately scour out deposited sediments and prevent inlet closure. For a given wave environment,
inlet stability is governed primarily by the volume of water(tidal prism) carried by the inlet. To
remain stable, an inlet must have the characteristic that a temporary constriction in cross sectional area
produces an increase in current velocities adequate to scour out the constriction. To function without
mechanical intervention, the system must generate a sufficient volume of water on the ebb tide to scour
out the inlet naturally, otherwise the inlet will, over time, continue to close. This is particularly true
during periods of high wave activity and low tidal ranges. (Turrell 1995;Tackney 1996). The six
closures of Clam Pass that have occurred in the past twenty-five years indicate that stability of Clam
Pass is marginal. (Turrell 1995;Tackney 1996,Humiston 2010).
Hydrologic studies have indicated that during a tidal cycle, 75-80% of water that flows through the
Seagate culverts originates in Clam Bay,while 20-25%of water that flows through the Seagate
culverts comes from Venetian Bay(PBSJ 2009). Enlarging the Seagate culverts is not recommended
because it would further reduce the tidal prism of the Bay, and decrease the stability of Clam Pass
(DER 1981;Tackney 1996).
Since implementation of the 1998 Management Plan,the hydrologic conditions of the Clam Bay
System have improved considerably,resulting in the restoration of the mangrove forest.
26
1
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Inlet Dynamics
Clam Pass is a small wave-dominated inlet on the southwest coast of Florida that provides a tidal
connection to approximately 500 of the 570 acres in the Clam Bay NRPA, of wetland preserve. The
relatively small tidal prism of Clam Bay provides a critical balance between tidal flow in and out of the
inlet channel and littoral processes moving to the inlet. This affects the inlet hydraulic efficiency over
time, especially when littoral transport rates are high due to periods of high wave energy.
The morphologic features of a tidal inlet include ebb shoal,flood shoal, and inlet channel. The flood
shoal includes the sand shoals on the bay side of the inlet channel. The flood shoal is less dynamic
than the gulf side of the inlet as it is influenced mainly by tidal flow and sheltered from the varying
wave conditions on the open coast side. The ebb shoal features can be explained as sand bar features
forming a delta on the open coast side of the inlet. The ebb shoal delta shields the inlet channel from
waves and provides pathways for sand transport along the coast to bypass the channel without shoaling
the inlet closed.
1
,
' rii�rtil_ 0 ,
Figure 15:Ebb and Flood Shoals.Figure provided by Humiston&Moore
A stable inlet system requires an ebb shoal feature that prevents rapid shoaling at the inlet mouth. The
inlet channel maintains its flow cross section through tidal flow that scours the channel to required
flow area while the waves are moving large amounts of sand along the coast. The stability and
dynamics of a tidal inlet are based on the balance of the two forces of tidal flow versus wave-induced
current and sand transport. The direction of wave action plays a significant role in the shape and
dynamics of the inlet features.
Clam Pass is critically stable but subject to shoaling, and therefore requires regular monitoring to
determine if dredging is needed. The relatively small bay area compared to other estuaries in
Southwest Florida provides adequate tidal flow to keep the Pass open under typical conditions. The
narrow nature of the flood shoal area surrounded by the mangrove forest limits the flood shoal capacity
27
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
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May 30,2014
Ver. 6.2
to maintain an equilibrium volume and bypass additional sand to the Gulf and bay waters. The
accumulation of sand over long periods of time, especially within the flood shoal and inlet channel
creates additional resistance to flow. This additional resistance causes a reduction in the tidal range
within the bay system and consequently reduces the flow through the Pass. Maintenance dredging to
restore flow rates may be needed.
During the 1990's Clam Pass was subject to channel migration as well as closure, and dredging was
necessary to keep the inlet open. In 1998 the Pelican Bay Services Division developed the Clam Bay
Restoration and Management Plan that was approved by the Collier County Board of Commissioners.
The purpose of the plan was to address the mangrove die-off by improving tidal flushing into and out
of the mangrove forest areas. This was accomplished through the dredging of Clam Pass and portions
of the interior creeks within the system, as well as the construction of a network of hand-dug channels
throughout the original die-off area and several other areas that were exhibiting stress. The
implementation of the Clam Bay Restoration and Management Plan resulted in a significant increase of
the tidal prism compared to conditions prior to 1999 and the eventual recovery of over 90%of the
original mangrove die-off area.
Clam Pass requires regular monitoring to determine when dredging may be needed. In addition to the
1999 dredging, dredging occurred in 2002,2007, and 2013. The 2013 dredging took place following
inlet closure in late 2012 after the passage of Tropical Storms Debbie and Isaac and high-energy wind
and wave conditions. The inlet was reopened in April,2013 and tidal exchange between the bay and
the Gulf of Mexico was restored to near design levels.
Chapter 4.0 of this Management Plan outlines the scope of the monitoring efforts and factors that will
be considered prior to a determination to dredge Clam Pass.
Freshwater Component
Under predevelopment conditions,much of the area's rainfall was held on the surface of the land in
sloughs and other low areas. This water would either slowly filter through the soil to recharge the
shallow aquifer or move through the mangrove community to the bay. Less than ten inches of the
approximately 53 inch average rainfall is estimated to have been lost from the uplands east of Clam
Bay as surface runoff. The storage capabilities of the land thus moderated surface flows,preventing
extremely high flow rates during the rainy season and serving to maintain surface flow and
groundwater flow during the dry season(FDER 1981).
The development of Pelican Bay had limited fill impact to the Clam Bay system,but it did modify the
pattern of freshwater entering the Clam Bay system(Wilson,Miller et. al., 1996). The stormwater
management system as designed,permitted, and implemented at Pelican Bay employs a series of
detention ponds, swales, and culverts to regulate the discharge of run-off into Clam Bay. Discharge
occurs almost continuously along the eastern perimeter of the conservation area. Run-off from the
northern end of Pelican Bay is collected and discharged into Upper Clam Bay. Irrigation water for 27
holes of golf and landscaping in Pelican Bay is approximately 3.0 MGD which approximates 26 inches
per year of additional rainfall equivalent(Wilson, Miller et. al., 1996). When added to the average
28
CLAMBAYNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
rainfall for South Florida of approximately 53 inches per year,the local area has an effective rainfall of
approximately 80 inches plus annually. This is significant,particularly when viewed in the context of
predictable storm events that have the potential for altering the amount of average rainfall entering the
Clam Bay system.
The"Pelican Bay Water Management System—Stormwater Detention Volume and Water Budget
Analysis" (Wilson,Miller,Barton&Peek, Inc. April, 1996)describes the water management system
as being divided into six watershed or drainage systems. Rainfall,including irrigation,reaches the
ground and either seeps into the ground or runs off to a stormwater detention area within each system.
The stormwater detention plan for Pelican Bay has a standard,permitted design capacity to hold the
first inch of stormwater during a 25-year storm event. The stormwater is detained for flood protection
and water quality treatment. Stormwater discharge is controlled by a series of weirs designed such that
the post-development stormwater run-off rate does not exceed pre-development rates. Stated
differently, the system is designed to discharge stormwater in the development portion of Pelican Bay
in the same manner that it discharged stormwater prior to development. The stormwater discharge is
gravity driven and exits the weir system for a final release into Clam Bay.
Stormwater runoff from an additional 130 acres of watersheds, outside of Pelican Bay, contributes a
supplementary and significant volume of discharge to Clam Bay. This water represents 7.9%of the
total stormwater discharge to Clam Bay.
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or
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Figure 16:Approximate locations of Drainage Basins within the Pelican Bay Development(photo is oriented with north up
and west to the left).
As the area of Pelican Bay to the east has undergone development, it has increased the impervious
surface area,with a concomitant increase in surface runoff,which is eventually discharged to Clam
29
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Bay. The daily irrigation water volume enhances the saturation of the uplands which reduces their
ability to accommodate rainfall volume,thus effectively increasing surface and groundwater discharge.
Groundwater discharge can be commonly observed throughout the eastern side of Clam Bay and is
discernible as a very slight sheet flow. Where this water encounters a discharge system,even one that
is not operating at peak efficiency(from an engineering,not historical, standpoint), such as Outer Clam
Bay, excess water is effectively removed from the system. However, in the northern section, sheet
flow was not being efficiently removed at the time of the mid-1990 mangrove die-off due to lack of
flow through the forest. Thus,it accumulated,increasing soil saturation and raising the mean water
table elevation, and apparently overwhelming the black mangrove's anaerobic soil/gas exchange
mechanisms. Mangroves in these areas became stressed and died. Subsequent activities undertaken as
part of the 1998 Management Plan have resulted in the reestablishment of mangroves throughout the
die-off area.
Water Quality
During the initial environmental permitting of Pelican Bay,the agencies required water quality testing
within the Pelican Bay subdivision and the Clam Bay estuary to help evaluate the impact of
development on Clam Bay. The water quality testing program was first implemented by the Pelican
Bay Improvement District(PBID) starting in the early 1980's. In 1990 the PBID became the Pelican
Bay Services Division(PBSD), a dependent Division of Collier County. The PBSD continued the
testing program after 1990. The PBSD is currently the responsible entity for the testing program.
The water quality testing is performed at several sample points within Pelican Bay and Clam Bay. The
sample point locations are shown on the Figure 17 on page 31. There are currently nine sampling
locations within Pelican Bay and Clam Bay. Sample points W-7(located in the creek near the north
Pelican Bay Foundation boardwalk);W-6 (located in the creek near the south Pelican Bay Foundation
Boardwalk);W-1 (located near the kayak launch area at the southern end of Outer Clam Bay);North
Seagate(located on the north side of the Seagate culverts between Venetian Bay and Outer Clam Bay);
and Upper Clam Bay(located at the very north end of Upper Clam Bay) are within Clam Bay, which
are categorized as Class II waters by the FDEP. The remaining five sampling points are PB-13
(located north of the Sandpiper parking lot on both sides of the berm);PB-11 (located between the St.
Maarten condominium and the Commons on the east side of the berm); Glenview(located between the
Glenview and Stratford condominiums on the east side of the berm); and St. Lucia(located adjacent to
the St. Lucia condominium on the west side of the berm), are located in the stormwater treatment
portion of the property(Class III waters)within Pelican Bay.
30
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
y t. s t- 4 • . . y ` _ 1f a
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ig-
Figure 17: Water Quality monitoring locations within the NRPA Boundary
31
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Water quality sampling is conducted within the Clam Bay system on a monthly basis. The samples are
collected by PBSD staff and transported to the Collier County Pollution Control laboratory for
processing. Parameters sampled and collected, include:
• Field pH
• Field Temperature
• Field Salinity
• Field Dissolved Oxygen
• Ammonia
• Carbon—Total Organic
• Chlorophyll a
• Copper(added to the parameter suite in 2013)
• Nitrate-Nitrite(N)
• Nitrite(N)
• Nitrogen—Total Kjeldahl
• Orthophosphate(OPO4)
• Pheophytin
• Phosporus -Total
• Residues—Filterable(Total Dissolved Solids(TDS))
• Silica(SiO2)
Water quality sampling results of nutrient loading seem to indicate that the development stormwater
management system is doing its job. No evidence of nutrient loading has been observed within the
Class II waters though several spikes and elevated nutrient(N and P)levels have been observed from
the testing locations along the berm. It is believed that the spikes observed are correlated with
fertilizer application within the community.
The FDEP conducted water quality sampling within the Clam Bay NRPA in 2011 and 2012. Based on
their sample results,FDEP had made an initial determination that Clam Bay could be impaired for both
Dissolved Oxygen(DO) and Copper. Subsequent coordination between FDEP, PBSD,the Pelican Bay
Foundation, and involved consultants,FDEP made a determination that the oxygen levels in Clam Bay
were natural, and the system was not listed as impaired for DO.
TMDL(Total Maximum Daily Load) are defined by the FDEP as the maximum amount of a given
pollutant that a surface water can absorb and still meet water quality standards. FDEP did determine
that the Clam Bay System was impaired for copper and was placing the Clam Bay system on the
Everglades West Coast verified list for copper with medium TMDL priority(5 to 10 years for TMDL
development). Subsequent copper testing undertaken by PBSD has also shown periodic elevated
levels of copper within the Clam Bay Class II waters.
FDEP acknowledged that the Pelican Bay community is developing an upland stormwater and nutrient
management program that is designed to reduce nutrient and copper inputs into the stormwater system.
Once completed,this program can be given to FDEP for review and if satisfied with the anticipated
reduction of copper resulting from the implementation of the plan,the system could be removed from
32
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
the impaired list. While the upland nutrient management plan is not part of this Management Plan,
PBSD will work closely with the Pelican Bay Foundation to coordinate and share information and to
integrate management decisions and activities into this Management Plan where appropriate.
Archaeological Resources
The Florida Division of Historical Resources Master Site File lists three known archaeological sites
within the Clam Bay NRPA boundary. All three are located within the mangrove forest habitat. Two
of the sites(CR476 and CR547) are located north of the Pass and south of Inner Clam Bay. The third
site(CR576)is located south of the Pass and north of the Clam Pass Park boardwalk.
Site CR476 is identified as a prehistoric campsite and shell midden possibly supporting the use of
several cultures dating from 8500 B.C.to A.D. 1700.
Sites CR547 and CR576 are identified as shell middens which were in use between 100 B.C. and A.D.
1700.
All three of the sites are within the mangrove forest and outside of the footprint of any previous or
future anticipated dredging activities.
Recreational Use
The Clam Bay NRPA provides a variety of opportunities for recreation, such as walking,kayaking,
canoeing,paddle-boarding, swimming, fishing, and snorkeling. Many Collier County residents and
visitors enjoy the natural environment of the preserve. Recent stakeholder input as well as prior
reports supports the use of the Clam Bay NRPA for low-impact recreation. It is important that all who
participate in recreational activities within the system do no harm to the unique flora and fauna of the
Clam Bay NRPA.
Clam Bay's dense forest of mangroves significantly limits walking in the preserve. Most walkers
seeking to enjoy the rich natural environment of Clam Bay use the three boardwalks that cross the
preserve and provide access to the beach. Residents and guests of Pelican Bay use the northern and
middle boardwalks. The southernmost boardwalk is open to the public and accessed from the parking
lot at the south end of the system. Trams are used on all three boardwalks to transport those choosing
not to walk on the boardwalk to the beach.
Fishing and swimming are popular pastimes. Fishing can be done from the boardwalks and canoes or
by wading into the water. Swimming is usually confined to the beach areas,but some swimmers and
waders, if conditions permit,venture into Clam Pass.
Kayaks, canoes, and paddleboards are used by those wanting to enjoy the natural setting and serenity
of Clam Bay's waterways.There is a public launching area for non-motorized vessels adjacent to the
parking lot at the south end of Outer Clam Bay. There is also a launch area for Pelican Bay residents
33
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
on the northern boardwalk. The canoe/kayak trail is clearly designated by canoe trail markers from
Outer Clam Bay to Upper Clam Bay.
Occasionally,motorized vessels, including boats,jet-skis or other personal watercraft,have been
observed operating in a manner that may be in violation of Florida Statutes. Appropriate County
Ordinances regarding vessel operation may be sought in the future to ensure that Clam Bay remains a
safe environment for all recreational users.
34
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
4.0 Management Plan Goal and Supporting Objectives
The following goal and supporting objectives for the management of the Clam Bay Natural Resource
Protection Area(NRPA) were developed in accordance with the directives of the Collier County Board
of Commissioners (BCC) and the Pelican Bay Services Division(PBSD), which serves as an advisory
board to the BCC. The goal and supporting objectives were formed in conjunction with stakeholder
input and are based on the management issues present in the NRPA as well as the purposes for which
the land is held in public trust.
The Clam Bay NRPA requires active management to ensure its long term health. The goal and
supporting objectives set forth in this plan should not appreciably change over time, but management
techniques and strategies may be modified to appropriately manage the NRPA. Annual reports will be
completed documenting the results and analysis of all monitoring activities over the course of the
previous year.
The ability to implement specific objectives of the management plan is dependent upon available
administrative and fmancial support. Therefore, activities will require prioritization to remain within
available funding. Management strategies will be reviewed annually and adapted as needed.
GOAL
The goal of the Clam Bay NRPA Management Plan is to establish the basis for management
activities that will be undertaken to protect the health of the Clam Bay NRPA estuary.
Objectives to support this goal include:
1. Maintain and protect the native floral and faunal communities within the Clam Bay NRPA
2. Ensure the estuary has adequate tidal and freshwater flows to maintain ecological health
within the Clam Bay NRPA
3. Monitor and maintain water quality within the Clam Bay NRPA
4. Monitor archaeological sites within the Clam Bay NRPA
5. Ensure recreational activities are environmentally compatible within the Clam Bay NRPA
These objectives were formed to allow for adaptive management, whereby the compilation and
analysis of all data will occur holistically and provide direction to adjust strategies to better achieve the
goal.
35
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Objective 1 —Maintain and protect the native floral and faunal communities within the Clam Bay
NRPA
A. Maintain healthy,native floral and faunal populations
• Establish plots and photo points in Scrub and Hammock habitats and monitor
periodically.
• Monitor established plots in the mangroves periodically.
• Monitor established transects in the seagrasses periodically.
• Update a list of observed wildlife periodically.
• Monitor benthic organisms periodically.
B. Protect Listed Species
• Monitor gopher tortoise burrows periodically.
• Report Collier County's sea turtle nesting findings as they become available.
• Update the species list in the NRPA as new species are sighted.
• Conduct appropriate wildlife surveys prior to disturbance events.
• Update educational information on species, such as the Clam Bay Guide as needed.
C. Remove Exotic and Nuisance Flora and Fauna
• Locate and identify exotic, nonnative, and nuisance species.
• Remove, or report to the responsible entity for removal, Category I and II invasive
exotic species and nuisance species as needed.
36
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Objective 2—Ensure the estuary has adequate tidal and freshwater flows to maintain ecological
health within the Clam Bay NRPA
A. Identify the minimum tidal flow necessary to ensure a healthy ecosystem. Provide
sufficient tidal exchange to maximize benefits while minimizing negative environmental
impacts.
• Conduct periodic bathymetric surveys of Clam Pass.
• Conduct periodic analysis of tidal data.
• Maintain tidal gauges.
• Conduct bathymetric surveys of interconnecting waterways when needed.
• Determine through regular biological monitoring whether ecological health warrants
intervention strategies.
• Seek appropriate federal and state permits to dredge Clam Pass or interconnecting
waterways if needed.
• Monitor identified variables of Clam Pass conditions to determine when dredging is
needed. (See Chapter 5 and Appendix 5 for information on variables.)
B. Ensure appropriate freshwater inputs and drainage
• Conduct periodic monitoring of hand-dug channels.
• Perform periodic maintenance of selected sections of hand-dug channels.
• Develop intervention strategies if data documents the need.
Objective 3—Monitor and maintain water quality within the Clam Bay NRPA
A. Develop a long-term water quality program that ensures a sustainable healthy
environment for all users
• Continue a program of water quality data collection, making certain that all protocols
and sampling locations comply with FDEP guidelines and standards and addresses the
Site Specific Criteria approved by FDEP.
• Review and report water quality data, including comparison to historical data and in
conjunction with biological data.
• Develop intervention strategies when standards are not met.
• Enter data into STORET system on an annual basis.
• Develop a plan to address copper impairment in Clam Bay.
B. Support programs for controlling water pollution from point and nonpoint sources
• Support Best Management Practices for fertilizer and irrigation use in Pelican Bay.
• Support programs to reduce algae levels in upland stormwater ponds in Pelican Bay.
• Support programs to reduce additional copper input into stormwater ponds in Pelican
Bay.
37
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Objective 4—Monitor archaeological sites within the Clam Bay NRPA
A. Monitor conditions of known archaeological sites.
• Review historical records of Florida Division of Historical Resources (DHR) on known
archaeological sites.
• Inspect known archaeological sites periodically.
• Report findings as appropriate to DHR.
B. Implement strategies for the protection archaeological sites as needed.
Objective 5—Ensure recreational activities are environmentally compatible within the Clam Bay
NRPA
A. Monitor access and the condition of the facilities for recreational uses.
• Report vegetation needing to be trimmed to the responsible entity.
• Report litter needing to be removed to responsible entity.
• Report facilities needing to be repaired or replaced to responsible entity.
B. Maintain existing canoe trail.
• Inspect signage periodically.
• Repair or replace signage as needed.
• Repair or replace seagrass and caution shoaling signs.
• Revise and/or reprint the canoe trail guide as needed.
C. Maintain existing signage for safe swimmer and boater usage.
• Inspect signage periodically.
• Repair or replace signage as needed.
D. Monitor use of facilities/area for recreational uses.
• Encourage citizens to report unsafe or environmentally harmful use.
• Coordinate with responsible entity to enforce the laws and regulations as needed.
• Continue to support the use of the Clam Bay NRPA for low-impact recreational uses.
E. Maintain materials to educate visitors about the unique features of the Clam Bay NRPA
• Inspect signage periodically.
• Report signage needing repair or replacement to the responsible entity.
38
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
5.0 Clam Pass Dredging
A. Dredging Policy
There are two circumstances that could necessitate dredging Clam Pass.
1. Clam Pass closes completely due to a storm or natural event or is in eminent danger of
immediate closure following a weather driven event and such conditions are decided by
competent professionals to be uncorrectable through the dynamics of natural hydrological and
meteorological processes. In this situation the inlet should be dredged as soon as possible.
2. The inlet has lost hydraulic efficiency and is jeopardizing the health of floral and faunal
communities of the Clam Bay NRPA. This determination is made by reviewing and comparing
current and past data from tidal hydraulic and bathymetric monitoring data.
In both cases the PBSD Board would, after consultation with and advice from its consulting coastal
engirneer, approve and recommend an appropriate set of construction drawings for the dredging event
to the BCC for its approval prior to the submittal to the regulatory agencies.
Dredging will only be done for the health of the Clam Bay NRPA,not for navigation or beach
renourishment. Beach compatible sand removed as part of the dredging event will be spread on
adjacent area beaches, as required by the permitting agencies.
B. Dredging Criteria
The purpose of regular monitoring is to evaluate inlet characteristics on a comprehensive long term
basis with less emphasis on short term or seasonal changes.
To monitor the stability of Clam Pass, data on the four variables listed below will be regularly
collected. They will be reviewed by the consulting engineers. If data are not within the identified
target ranges for the variables, further monitoring and/or intervention will be considered. See
Appendix 5 for additional information on the dredging criteria.
1. Bay Tide Range
Tidal range data have been collected annually since 1999 and will continue to be collected and
reported to the consulting engineer at least quarterly. An annual tidal analysis report will be included
with the annual report.
Data are collected from gauges at four locations(Clam Pass Park Boardwalk,Pelican Bay South
Boardwalk,Pelican Bay North Boardwalk, and Upper Clam Bay). These gauges provide a record of
the tidal range within Clam Bay and are one indication of the tidal prism or volume of water flowing
through Clam Pass at each tidal cycle.
39
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Based on an analysis of data from the gauges at the South Boardwalk and Clam Pass Park Boardwalk
from 1998 to the present when the inlet was hydraulically stable,the ratio between Clam Bay and Gulf
tide was between 0.6 and 0.7 over 90% of the time. Therefore, if the ratio between Clam Bay and the
Gulf tide falls below 0.6,but above 0.5, further monitoring will be considered once it has been
established that other types of blockage are not causing the problem. If the tidal range ratio falls below
0.5,physical monitoring of, or interventions to,potential shoaling areas that could be impeding flow
will be considered.
2. Cross Section of Flow Area and Volume of Shoaled Material
Annual bathymetric surveys and reports were completed from 1999 to 2008. Bathymetric surveys
provide data on the physical conditions of the inlet channel, ebb shoal and flood shoal. Post-dredging
bathymetric surveys and reports were completed at 3-month, 6-month, and 12-month intervals
following the opening of Clam Pass in April 2013. Beginning in 2014,bathymetric surveys and
reports will be issued at least annually. Additional surveys will be considered if the hydraulic
efficiency falls below target levels.
To establish benchmarks or targets for flow area and volume of shoaled materials,the data analysis
included evaluation of the flow cross-section areas in the three main sections of the dredging region.
Section A represents the inlet channel, Section B the seaward part of the flood shoal, and Section C the
bay side part of the flood shoal.
Section C
Section A
Figure 18:Sections A,B and C
The analysis included evaluation of the cross-section of flow between mean high water and the volume
of sand within each segment. The cross-section of flow was computed at each survey station spaced
40
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
approximately 50 feet apart. The average and minimum cross-section areas were used as indicators of
the physical condition of the flow area of the three segments. The cross-sections were compared to the
design cross-section area of the 2013 dredging and the inlet conditions in 2004 and 2008 when inlet
conditions were near equilibrium 24 months and 16 month, respectively, following dredging events.
Targets for the average cross-section of flow areas:
Section A greater than 300 sq. ft.
Section B greater than 450 sq. ft.
Section C greater than 450 sq. ft.
Targets for the minimum cross-section flow areas:
Section A greater than 250 sq. ft.
Section B greater than 350 sq. ft.
Section C greater than 350 sq. ft.
Targets for volume of shoaled materials:
Section A less than 3000 cu. yds.
Section B less than 2500 cu. yds.
Section C less than 4000 cu. yds.
Therefore, if the average cross-section of flow area falls below these numbers or the volume of shoaled
material exceeds these numbers, further monitoring or intervention may be needed.
3. Inlet Channel Length
The channel length is an important factor in inlet stability. A longer inlet channel will provide greater
resistance to flow. Higher flow resistance will reduce the tidal range and increase the phase lag with
the Gulf tide that reduces the tidal prism and flow through Clam Pass.
To establish a benchmark for channel length a selection of aerial photos of Clam Pass from 2004 to
2013 was studied as well as data on the approximate length of the channel following dredging events
in 2002, 2007, and 2013.
Based on this analysis,the benchmark for inlet channel is to stay under 400 feet in length. Inlet
channel length will be recorded at least annually and included in the annual report.
4. Ebb Shoal
The size and shape of the ebb shoal is a key factor to the stability of the inlet that, in turn, supports the
stability of Clam Pass. The ebb shoal helps to keep the inlet open when facing stonus and big wave
events. The ebb shoal delta provides sheltering to the channel and sand bypass pathway around the
inlet without filling in the Pass. The shape and volume of the ebb shoal are additional indicators of the
stability of the inlet. Critical conditions include onshore collapse of the ebb shoal that can be indicated
41
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
by significant change in ebb shoal offshore distance,volume, and increase in dry beach areas adjacent
to the inlet.
To determine a target for the ebb shoal delta, data from April 2013 to April 2014 were reviewed. The
ebb shoal position offshore is measured from a line connecting the north and south channel banks at
mean high water out to the-4.0 foot contour line.
The recommended length of the seaward extent of the ebb shoal is at least than 250 feet. The ebb
shoal distance from shore will be recorded at least annually and included in the annual report.
Dredging Criteria Parameter Summary
Location Target Description
Bay Tide Range Ratio >0.6 ratio comparison of the interior and Gulf
tidal ranges
A Average>300 sq ft
Not less than 250 sq ft
Cross Sectional Area Average>450 sq ft area in different locations of the Pass
Not less than 350 sq ft through which water can flow
C Average>450 sq ft
Not less than 350 sq ft
A <3000 cu yds
Volume of Shoaled Material B <2500 cu yds quantity of sand and sediments within
C <4000 cu yds channel that can restrict flow
<400 feet distance water must flow through the
Inlet Channel Length beach and ebb shoal areas
Ebb Shoal >250 feet distance from shore to the outer ebb
shoal limits
C. Dredging Construction
1. Typical Cross-Sections for Dredging
Typical cross-sections for the suggested dredge template are provided below. When dredging is
deemed necessary, the design cross-section area as stated in the design range, with consideration to
existing conditions, will be followed. Minor modifications to this dredging template may be needed
for future permitting. Typical cross-sections are shown for open areas in Section B and C where the
waterway is wider than the target cross-section. In areas where the waterway is limited by mangroves,
the width of the cut will be limited to maintain a minimum of a five-foot buffer to the mangroves. In
Sections B and C where seagrasses may be present every effort will be made to avoid dredging
activities that would be harmful to seagrasses.
42
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
2013 Target Proposed
Dredged Area Design •
_
area
Below 312 300 300 3
MHW
8 " ,
SECTION A — TYPICAL .'
8- 5 C1 OU A
c 4-
`J - CRAUR:C1 laNIC5
Z 2— �, "
v -/.110 (+0.33')
lWi..-2— I,SIJESLUPC,V:I{{ ,+
Z
O
r-4- f _onan CUT(-3.0'wev0
W—8- bp' ..
—10- NORTH SOUTH
—12
—200 —150 —100 —50 00 100 150 200
DISTANCE FROM CENTER (FEET)
1451 Figure 22.Typical Maintenance Dredging Cross Section-Inlet Channel-Section A
28
Figure 19: Typical maintenance dredging cross section—Inlet Channel—Section A figure provided by Humiston&
Moore)
43
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
2013 Target Proposed
Dredged Area Design
area
Below 650 450 450
M H W \
8 6 ` r ;ECTicii a
SECTION 9 - TYPICAL
6—
o d-
> -
4 2
.z• - i
-1.1HY!(+0,330 , __ _... __.. _.__-__.. _ _ _
-2- i
SICMLorc
z -
O f CMN cut r a.e ka_1
-e-
-10-
- NORTH SOUTH
-12-
-200 -150 -100 -50 0 50 100 150 200
DISTANCE FROM CENTER (FEET)
Figure 23.Typical Maintenance Dredging Cross Section—Seaward Flood Shoal—Section B
so
Figure 20:Typical maintenance dredging cross section—Seaward Flood Shoal—Section B(figure provided by Humiston&
Moore)
44
CLAM BAYNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
2013 Target Proposed
SECnOV C
Dredged Area Design
Area area •
Below 530 450 450
MHW i
SECTION C - TYPICAL
4-
2-uHN(ra.S]')
st19[OP[violn.-2- ll
e-4_
-a-
-t9- NORTH SOUTH
-200 -150 -100 -50 • 0 50 100 150 200
DISTANCE FROM CENTER (FEET)
Figure 24.Typical Maintenance Dredging Cross Section-Bayside Flood Shoal-SectionC
1
Figure 21: Typical maintenance dredging cross section—Bayside Flood Shoal—Section C(figure provided by Humiston&
Moore)
45
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
6.0 Authorized Construction Activities
List of Permits for Work Undertaken to Date and Relevant Legal Framework
FDEP and USACE 10-year permits will be sought in conjunction with this new Management Plan,
after the application is approved by the PBSD and BCC. The permits will allow for ongoing
maintenance activities to continue along with occasional,modest removal of material by dredging
within a discreet area of Clam Pass in order to maintain the existing tidal regime within the system.
Any changes to the submitted dredging scope or other new management initiatives will be reviewed by
the PBSD Board and Collier County Commissioners before seeking any additional permit(s)which
may be necessary for the modified activities. Additional investigations which may be undertaken at a
later date to look at, for example, faunal investigations,more in-depth water quality concerns, or other
issues that may arise as a result of Stakeholder discussions could also necessitate pennitting which will
have to be reviewed by the PBSD and BCC prior to any such permit applications being submitted.
This Management Plan is specifically tasked to maintain the improvements and benefits already
realized and to insure that the restoration success observed to date is continued. Dredging for
navigation or beach renourishment will not be done.
Appendix 1 contains the timeline of important events within the Clam Bay system and a list of
authorizations brief details related to existing and historical permits issued for the Clam Bay system.
46
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
7.0 Clam Bay NRPA Management Plan Amendments
The Management Plan is not expected to be a static document and ongoing research and data collection
related to water quality; hydrographic changes in the various areas of the system;benthic community
health;mangrove community health; exotic and nuisance vegetation control; and public education will
be conducted and/or collected. Conclusions,recommendations, or alternative management activities
that come about as a result of studies conducted outside of the scope of this Management Plan will be
examined and considered by the Pelican Bay Services Division and its consultants. Those
modifications that are found to be viable,pertinent and economically feasible alternatives or additions
allowed under the scope of this Management Plan will be added to the Management Plan. Those
changes in Management activities or new work items that are outside of the scope of the Management
Plan but are considered important or practicable by the Pelican Bay Services Division and its
consultants will be submitted to FDEP and USACE for consideration and inclusion into this
Management Plan.
47
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Clam Bay NRPA Management Plan Stakeholders Groups and Review Agencies
Review Agencies
City of Naples Collier County Natural Resources
Michael R. Bauer, J.D., Ph.D. Bill Lorenz
295 Riverside Circle 2800 N Horseshoe Dr
Naples, FL 34102 Naples,FL 34104
Collier County Parks and Recreation Florida Dept. of Environmental Protection
Maura Kraus/Barry Williams Megan Mills
15000 Livingston Rd P.O. Box 2549
Naples, FL 34109 Fort Myers, FL 33902
Florida Fish&Wildlife Conservation Comm. Florida Fish&Wildlife Conservation Comm.
Habitat& Species Conservation Div. Boating&Waterways Section
3829 Tenoroc Mine Rd 620 South Meridian St
Lakeland, FL 33805 Tallahassee, FL 32399
National Marine Fisheries Service South Florida Water Management District
263 13th Avenue S Laura Layman
St. Petersburg, FL 33701 2301 McGregor Blvd
Fort Myers, FL 33901
U.S. Army Corps of Engineers U.S. Fish and Wildlife Service
Tunis McElwain 1339 20th Street
1520 royal Palm Square Blvd, Ste 10 Vero beach, FL 32960
Fort Myers, FL 33919
Stakeholder Groups/Individuals
Collier County Audubon Conservancy of Southwest Florida
1020 8th Avenue S, Ste 2 1450 Merrihue Dr
Naples,FL 34102 Naples,FL 34102
Mangrove Action Group Naples Cay Association
P.O. Box 770404 40 Seagate Dr, Ste 1206
Naples,FL 34107 Naples,FL 34103
Paradise Coast Paddlers Club Pelican Bay Foundation
2392 Clipper Way 6251 Pelican Bay Blvd
Naples, FL 34104 Naples,FL 34108
Pelican Bay Property Owners Association Seagate Property Owners Association
801 Laurel Oak Dr, Ste 600 P.O. Box 3093
Naples, FL 34108 Naples,FL 34106-3093
Sierra Club—Calusa Group Southwest Florida Paddling Club
6075 Pelican Bay Blvd, #703 20991 S Tamiami Trail
Naples, FL 34108 Estero,FL 33928-2838
48
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30,2014
Ver. 6.2
Tall Tales Bait and Tackle The Ritz-Carlton Naples
841 Vanderbilt Beach Rd 280 Vanderbilt Beach Rd
Naples,FL 34108 Naples,FL 34108
The Seasons at Naples Cay Condo. Assoc. Waldorf Astoria Naples
81 Seagate Dr,#3000 475 Seagate Dr,
Naples,FL 34103 Naples,FL 34103
Diane Solomon Brown&Stuart Brown Sandra J Doyle
dianesolomonbrown@me.com naplespatriots@comcast.net
Anne Georger Brandon Lampe
ageorgerl@gmail.com brandonlampe@rocketmail.com
Diane Lustig&Leon Lustig Linda Roth
lustigl@embarqmail.com LOR3LOR3@aol.com
Missy Travis&Pat Travis Mary McLean Johnson
missy.travis@gmail.com 6573 Marissa Loop#1501
ptravis@delotte.com Naples,FL 34108
49
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
Clam Bay NRPA Management Plan Bibliography
1. Collier County Natural Resources Department. Clam Bay Natural Resources Protection Area
Management Plan Draft, technical paper-4th rev.Nov 21, 1994.
2. Collier County. Executive Summary—Approval of Clam Bay Natural Resources Protection
Area(NRPA). 21 Feb 1995.
3. Crewz, David W., 1989, Clam Pass Park mangrove damage, Department of Natural Resources
Interoffice Memorandum.
4. Crewz, David W. Florida. Department of Natural Resources. Clam Pass Mangrove Damage.
Interoffice Memo, May 1989.
5. Gee&Jensen Engineers,Architects and Planners, Inc., 1978, Hydrographic Study Clam Bay
System Collier County,Florida for Coral Ridge-Collier Properties Inc., report.
6. Hartwell, Richard W., Hatcher, James M., Grabe, Stephen,August 1994, Clam Bay Natural
Resources Protection Area(NRPA), Collier County Environmental Services Division,
Publication Series NR-SP-94-01,technical paper.
7. Hawkins, Mary Ellen, Obley, Ross P., "Pelican Bay-Visit and Revisit."Urban Land Vol. 40,
No 11. (December 1981) 21-27.
8. Heald,Eric J.,Tabb, Durbin C., Roessler,Martin A., Beardsley, Gary L., Ward, Gerlad M.,
Durrance, Dallas H., Yeend, John S., 1978, Carbon Flows in Portions of the Clam Pass
Estuarine System, Collier County, Florida, Tropical Biolndustries Company and Gee and
Jenson, Engineers-Architects-Planners, Inc., technical paper.
9. Heald,Eric J., Roessler, Martin A., December 1979, Invertebrate Population Studies in the
Vicinity of Upper Clam Bay, Collier County, Florida,Tropical Biolndustries,technical paper.
10. Heald, Eric J., July 1983, Populations of Melampus coffeus and Cerithidea scalariformis West
of Upper Clam Bay, Collier County, Florida, Tropical Biolndustries, Inc., technical paper.
11. Heald,Eric J., July 1983, Fish Populations of Tidal Ponds West of Upper Clam Bay Collier
County, Florida, Tropical Biolndustries,technical report.
12. Humiston and Moore Engineers. 2007. Clam Pass Restoration and Management Plan
Bathymetric Monitoring Report No. 8.
13. Humiston and Moore Engineers. 2010. Clam Pass Restoration and Management Plan
Bathymetric Monitoring Report No. 12.
50
CLAM BA YNRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
14. Humm, H.J. and Rehm,A.E. 1972. Ecological Appraisal an Ecological Study of the Clam Pass
Complex. Study for the Collier Company at Clam Pass Properties. Tri-County Engineering,
Inc. TCE Project No. 1516.
15. Lewis,Roy R., and Marshall, Michael J. Lewis Environmental Services. First Annual Report,
#2; One year after flushing channel construction. 1997.
16. Natural Resources Conservation Service. United States Depaitiiient of Agriculture. Soil
Survey of Collier County Area, Florida. 1998.
17. Tackney&Associates, Inc., Preliminary Hydrographic Assessment Clam Bay Systems. August
1996.
18. Tri-County Engineering, Inc., 1971, Tidal Datum Plane Determination for the Collier
Company.
19. Tri-County Engineering, Inc., Sarkar, Chiranjib K. Hydrographic Investigation of the Clam Bay
System, Technical paper. October 1972.
20. Tropical Biolndustries and Missimer and Associates, Inc.,A Comparative Study of the Water
and Carbon Flows of Upper Clam Bay, technical paper. June 1979.
21. Turrell &Associates,Inc. Environmental Assessment Northwest Fill Area for Pelican Bay,
technical paper. February 1979.
22. Turrell and Associates, Inc. and Humiston&Moore. "Clam Pass Inlet Management Plan
Interim Report No. 1". July 1995.
23. Turrell, Hall &Associates, Inc. 2009. Clam Bay Restoration and Management. Biological
Monitoring Report. Eighth Annual Report No. 11.
24. Wilson, Miller,Barton&Peek, Inc. Pelican Bay Mangrove Investigation,Pelican Bay Water
Management System-Stormwater Detention Volume and Water Budget Analyses. April 1996.
25. Worley, Kathy and Jeffrey R. Schmid. "Clam Bay Natural Resource Protection Area(NRPA)
Benthic Habitat Assessment-Report for the Contract Agreement Between Pelican Bay
Property Owners Association(PBPOA), Pelican Bay Foundation, Inc. (PBF), and the
Mangrove Action Group (MAG), and the Conservancy of Southwest Florida(CSWF). Dec
2010.
51
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
APPENDIX 1 - TIMELINE OF
IMPORTANT EVENTS WITHIN THE
CLAM BAY NRPA AND A LIST
OF PERMITS FOR Wo1K
UNDERTAKEN IN AND AROUND
THE CLAM BAY NRPA
Appendix 1 —Timeline of Important Events within the Clam Bay System
Timeline of Important Events Within the Clam Bay System
1920
A dirt road is built by Forest Walker running from the northeast to south portion of Pelican Bay,a
forerunner of US 41.
1950
Clam Bay ecosystem is part of a connected system of barrier islands,mangrove forest,passes and
waterways. The orientation of the beaches and passes would have changed seasonally with storms.
1952
Vanderbilt Beach Road is constructed,eventually severing connection with the Wiggins Pass system to
the north.
1958
Construction of Seagate Drive is completed severing flow into and out of the mangrove swamps to the
south. This area was subsequently dredged and excavated to become Venetian Bay.
, �- Vanderbilt Lagoon
i. `i i l i
Outer Clam Bay
Upper Clam Bay It .� '
S
w/ 3
1111 Venetian Bay
,. f pari' ._ ----- r..�
Circa 1952 Aerial Photograph Circa 1960 Aerial Photograph
Figure 2:Historic aerials
1972
Tri-County Engineering produces reports:
An Ecological Study of the Clam Pass Complex,published by Humm&Rehm
Hydrographic Investigation of the Clam Bay System
Coral Ridge-Collier Properties, Inc. (a partnership between Westinghouse and Collier Properties)acquires
the property and initiates development of Pelican Bay.
1974
Pelican Bay Improvement District(PBID)is formed to manage common property in Pelican Bay and
provide for long-term sustainable infrastructure.
1976
Three,bi-directional 24-inch culverts are placed under Seagate Drive to provide hydrologic connection to
Venetian Bay.
Report"Environmental Assessment for Development Approval"is prepared for Pelican Bay.
Clam Pass closes and is mechanically dredged by dragline to re-open the entrance;no records of
quantities or dredge limits are available.
1977
Pelican Bay PUD is approved,and construction commences.
1977-1979
Gee&Jensen Hydrographic Engineers conduct a series of tidal studies within the system and distribute
"A hydrographic study of Clam Bay system"in 1978.
1978
Tropical Biolndustries produces a report: Carbon Flows in portions of the Clam Pass estuarine system.
Ecological assessment work by Tropical Biolndustries for permitting of the northwest fill area notes a
small area of stressed and dead mangroves close to Upper Clam Bay.
1979
Environmental Assessment of the northwest fill area is distributed(Turrell, 1979).
Tropical Biolndustries produces biological reports:
A comparative study of the water and carbon flows of Upper Clam Bay
Invertebrate Population Studies in the vicinity of Upper Clam Bay
1981
Clam Pass closes and is mechanically dredged by dragline to re-open the entrance;no records of
quantities or dredge limits are available.
WCI,the developers of Pelican Bay,transfers title to Clam Bay to Collier County with the stipulation that
Clam Bay shall remain a conservation/preservation area in perpetuity.
1982
WCI deeds Clam Pass Park and Clam Bay to Collier County, and in accordance with the Pelican Bay
PUD,requires the County to seek approval of WCI or its successors for any modifications to Clam Bay.
1983
Tropical Biolndustries produces biological reports:
Fish populations of tidal ponds west of Clam Bay
Populations of Melampus coffeus (Coffee bean snail)and Cerithidea scalariformis(Ladder hornsnail)
west of upper Clam Bay.
1986
Collier County constructs a 2,900'boardwalk to provide access to the county park,south of Clam Pass.
1988
Clam Pass closes twice,first in the spring and again in the late fall after Tropical Storm Keith(November
23, 1988).
1989
Small areas of stressed and dying mangroves are noted by residents in the basin west of Upper Clam Bay
and east of The Strand in Bay Colony. A Department of Natural Resources(DNR)interdepartmental
memo highlights cause of stress as"the lack of adequate water circulation resulting from the closure of
Clam Pass".
First emergency dredging is permit received from DNR to re-open clogged Clam Pass,following memo
by David Crewz to the DNR highlighting problems and danger if the Pass was not reopened.
Clam Pass is mechanically dredged to re-open. Approximately 700 cubic yards of material are removed
from the mouth of the inlet and the south bend of the channel. Material is placed south of the Pass.
Multiple closures of the inlet occur during the construction process.
1990
PBID becomes a dependent district of Collier County called the PBSD.
1992
The area of dead mangroves is reported at 7 acres.
1994
Twenty acres of mangroves are reported dead.
1995
Clam Bay is approved by the BCC as Collier County's first NRPA(See NRPA boundary map on page 8
of this report).
Clam Pass closes following a winter storm event. Emergency dredging permit issued allowing opening of
the Pass,but no work farther back than 600 feet. Mechanical dredging is undertaken removing
approximately 5,000 cubic yards of material from the entrance of the pass.
1996
Clam Pass closes following a winter storm event. Permits to open Clam Pass received from the Florida
Department of Environmental Protection(FDEP),formerly DNR,and US Army Corps of Engineers
(USACE). Mechanical dredging event carried out at the entrance of the Pass.
Blasting and hand excavation were permitted and completed in 1997.
Mangrove die-off area is estimated at 50 acres.
1997
Clam Pass,on the verge of closing following a winter storm event,is mechanically dredged again under
modification to 1996 Permits. Interior portions of the flood shoal are dredged to station 6+10.
1998
Clam Pass is on the verge of closing again following a winter storm event. A mechanical maintenance
dredging event is carried out under modification to 1996 Permits. Interior portions of the flood shoal are
dredged to station 6+10.
Ten-year permits are received from FDEP and USACE for dredging Clam Pass and the interior channels,
including adjustments to the Seagate culverts and installation of hand dug channels throughout the
system. Associated monitoring work and storm and freshwater studies are required.
1999
Dredging work associated with CBRMP is implemented(Mgmt by PBSD)in the spring by Ludlum
Construction Company. Hydraulic dredging of Cuts 1,2,3,and 4 (see attached Exhibits) are carried out.
A 30 foot entrance cut is dredged.
Nt
i (50,- 1
One way flap valve is installed on Seagate culverts to allow flow from south to north.
Staff at The Conservancy of Southwest Florida commences a 3-5 year study of mangroves,surface water
level and elevation within the mangrove die-off area.
2000
Hurricane Gordon impacts the area with no inlet closure.
2002
Hydraulic maintenance dredging of Clam Pass flood shoals between stations 3+10 and 17+50(Mgmt by
PBSD)is completed to improve tidal circulation(see attached Exhibits). The entrance of the Pass is not
dredged during this event.
Flap valves on Seagate culvert are removed due to insufficient head differential causing them to act as
plugs instead of valves.
Canoe trail markers are permitted and installed through Clam Bay System.
2004
Hurricane Charley passes approximately 30 miles west of Clam Pass. A lot of sand is redistributed, but
the Pass does not close. Extensive limb and leaf loss is documented within the mangrove forest.
2005
Hurricane Wilma comes ashore about 30 miles south of Clam Pass. More limb and leaf loss is noted.
Pass does close.
Hurricane damaged mangroves along bay 2005 Same mangroves along bay 2007
Hurricane Wilma damaged mangroves before and after
2007
Hydraulic maintenance dredging of Pass and entrance channel is conducted between Stations 0+00 and
18+00(see attached Exhibits). The entrance to the Pass is dredged at 80 foot width(Mgmt by Collier
County Coastal Zone Management Dept.) This dredging is conducted for sand for beach renourishment.
2008
Tropical Storm Fay comes ashore about 30 miles south of Clam Pass. The area receives over 10 inches of
rainfall. Pass is not affected.
2009
1998 FDEP and USACE permits for maintenance of the Pass expire after 1-year extensions.
2010
Permits are issued to continue maintenance of hand-dug flushing channels through the system.
2011
White mangrove die-off is observed in central portion of the system and is found to be caused by a bark
beetle infestation of trees that had suffered cold temperature stress.
Benthic Habitat Assessment study completed within the Clam Bay NRPA by the Conservancy of
Southwest Florida. Study provides comprehensive mapping of benthic habitat compositions and
distribution throughout the Clam Bay NRPA.
2012
Canoe trail markers and informational signage are permitted and installed throughout Clam Bay.
The mouth of Clam Pass moves to the north near the Pelican Bay Beach Store. The northern shoreline of
the Pass is temporarily reinforced with the installation of concrete barriers.
Impacts from tropical storms Debby and Isaac,along with numerous winter storm fronts, cause the
closure of the Pass.
2013
A single event mechanical dredge is carried out in March under FDEP and USACE permits with an
entrance cut of 45 feet. Beach compatible material is placed north and south of the Pass above the mean
high water line.
Development of a new Management Plan is initiated through Stakeholder input and multiple public
meetings.
Timeline Specific to the Establishment of the Clam Bay NRPA
1976
Collier County Ordinance 76-30 zoned coastal areas environmentally sensitive lands as ST(Sensitive
Treatment).
1977
Approval of the Pelican Bay PUD(Ordinance 77-18)by Collier County. The PUD identifies 98 acres of
coastal mangrove wetlands to be filled in for development while preserving 570 acres of ST lands as the
Pelican Bay Conservation Area(35 acres in the south and 5 acres in the north would become parks
providing public beach access).
1981-82
Department of the Army Permit(79K-0282) authorizes the fill of the 78 acres of coastal wetlands(76
acres for residential development and 2 acres for public parking area). It requires 570 acres,including
Upper,Inner,and Outer Clam Bays,and their adjacent wetlands to be conveyed to Collier County and to
remain a conservation/preservation area in perpetuity for the use of the public. It also prohibites dredging
Clam Pass except to keep it open to the Gulf of Mexico.
1988
The Pelican Bay Conservation Area(570 acres)is approved and recorded as FL-64P by Congress and
becomes part of the Federal Coastal Barrier Resources System(CBRS).
1995
The BCC approves the County Natural Resources Department's recommendation to establish the
County's first NRPA,stipulating that it would have the same boundaries as the Pelican Bay Conservation
Area within the Pelican Bay PUD.
The Collier County Manatee Protection Plan is approved. It contains the recommendation to establish an
"Idle Speed/No Wake"zone throughout the Clam Bay/Clam Pass System.
1996
Collier County Ordinance 96-16: "The Clam Bay System Water Safety and Vessel Control Ordinance"is
approved. It establishes that the Clam Bay System is an"Idle Speed/No Wake"zone.
1998
The CBRMP is developed,implemented,and managed by the PBSD and their consultants.
FL Admin.Court Case No. 98-0324GM provided an interpretation that certain elements of the Collier
County Growth Management Plan(Conservation and Coastal Management Element)require protection of
habitats within NRPAs which support existing and potential uses by wildlife.
2008
Public Law 110-419 is adopted identifying the CBRS,Clam Pass Unit,FL-64P to be entirely located
within the existing boundaries of the Clam Bay NRPA.
2013
Work begins on new Clam Bay NRPA Management Plan under the PB SD direction.
List of Permits for Work Undertaken in and around the Clam Bay NRPA
Eighteen years ago, Collier County processed a permit to dredge limited areas of Clam Pass to facilitate
the movement of tidal water in and out of Clam Bay. The FDEP permit for this activity was issued on
March 28, 1996 with the companion USACE permit being issued on April 2, 1996. The FDEP permit
was modified on April 10, 1996 with the authorized work being undertaken and completed on April 17,
1996. The practical effect of implementing this Permit was to reopen the Pass,but it was clear that
without a more comprehensive strategy,this effort,standing alone,would not revitalize the Clam Bay
ecosystem.
A permit to improve the channel flow within defined areas of the Clam Bay system by a combination of
blasting and hand excavation was issued on June 26, 1996. The work was undertaken and completed in
two segments. The first channels were opened in August 1996,and the second channels were opened in
November 1996. The results of these two initiatives were positive in that measurable improvements in
tidal flow were discernible and with that have come improved conditions for natural re-vegetation.
A permit was issued on January 5, 1997 to construct a portable pump and pipe system as an interim
measure to divert impounded freshwater within the Clam Bay system to the Gulf while a more permanent
solution contemplated by the construction of an outfall structure was reviewed. This plan was never
implemented and is no longer being considered. it envisioned two pumps that would be operational when
the water surface elevation within Clam Bay exceeded a specified threshold. The Management Plan
anticipated the direct discharge of excess water into the Gulf with the expectation that this system would
augment the natural discharge through the tidal mechanism after severe storm events.
Subsequently,Collier County authorized the pursuit of a ten-year permit to allow the County,or its
designee(which in this case was the Pelican Bay Services Division),to maintain Clam Pass in an open
condition. The application, as filed,did not address any other issues affecting the operational
characteristics of Clam Bay and essentially mirrored the 1996 Permit described in the first paragraph
above. Agency comments and concerns which arose as part of the permit review led to the creation of the
1998 Clam Bay Restoration and Management Plan. The Management Plan addressed agency concerns at
the time and included provisions for adding one-way flap gates to the Seagate culverts,dredging within
three sections of the creek north of Clam Pass,a network of hand dug channels throughout the forest area,
in addition to the dredging of the Pass.This permit was issued in 1998 and the Management Plan created
in support of the permit has been the guiding document for the maintenance activities undertaken in the
Clam Bay system since then.
Permit Details
South Florida Water Management District Surface Water Permit No.: 11-00065-S
Date of Issue: August 10, 1978
Expiration Date:Operational phase doesn't expire
Project Description:To construct and operate water management systems 1 and 2 serving 539 acres of
residential lands discharging by westerly sheet flow to Inner,Outer,and Upper Clam Bays.
Department of Environmental Regulation Construction Permit/Certification No.: 11-50-3769
Date of Issue:May 23, 1979
Expiration Date: May 15, 1984
Project Description:To provide construction sites for residential development in a planned community
by:placing approximately 700,000 cy of clean upland fill material onto approximately 94 plus acres of
submerged lands of waters of the state landward of the line of mean high water.
Department of the Army Corps of Engineers Permit No.: 00754929
Date of Issue:November 18, 1981
Expiration Date:November 18, 1984
Project Description:This permitted the filling of 75±acres of mangrove wetlands north,east,and west of
Upper Clam Bay and south of Vanderbilt Beach Road.
Department of Environmental Regulation Modification Permit No.: 11-50-3769
Date of Issue:December 23, 1981
Expiration Date:November 18, 1986
Project Description:This modification extended the expiration date of the permit to November 18, 1986.
Department of the Army Corps of Engineers Permit No.: 79K-0282
Date of Issue:August 2, 1983
Expiration Date:November 18, 1986
Project Description:This was an extension of the permit authorizing the filling of 75±acres of mangrove
wetlands north,east,and west of Upper Clam Bay and south of Vanderbilt Beach Road,plus
approximately 2 acres of mangroves at the existing Collier County beach access at Vanderbilt Beach
Road. The request was reviewed,and no objections were raised to the proposed work schedule;therefore,
the completion date of the permit was extended for 2 years until November 18, 1986.
South Florida Water Management Plan Modification of Surface Water Management Permit No.: 11-
00065-S
Date of Issue:December 15, 1983
Expiration Date: Operational phase doesn't expire
Project Description:Approved modifications to 1.)Revise system V,drainage area 3;2.)Construction
and operation of water management system number VI.
Department of Environmental Regulation Permit/Certification No.: 110974055
Date of Issue: September 12, 1985
Expiration Date: September 11, 1987
Project Description:To construct approximately 2900 linear feet of 10' wide public access elevated
boardwalk and pier with a 6' wide navigation access lift gate in Outer Clam Bay.
Department of the Army Corps of Engineers Permit No.: 861PT-20328
Date of Issue:December 18, 1986
Expiration Date: December 18, 1991
Project Description:Discharge±2.3 acres of clean fill to construct an access road.
Department of Environmental Regulation Modification Permit.: 11-50-3769
Date of Issue:January 7, 1987
Expiration Date: December 18, 1991
Project Description:This permit modification extended the expiration date and reduced the amount of fill
in the area extending south along the coastal edge from approximately 13 acres, as permitted,to 2.43
acres in order to construct a linear access road(for The Strand in Bay Colony).
Department of Environmental Protection Permit/Certification No.: 112659015
Date of Issue: March 14, 1995
Expiration Date: March 14,2000
Project Description:Re-establish the connection between the Gulf of Mexico to the Clam Bay system,by
dredging from the mouth of Clam Pass and spoiling the sand over an upland beach site.
Collier County Ordinance No.: 96-16
Date of Issue:April 9, 1996
Expiration Date: n/a
Project Description:To impose idle speed/no wake zones in the Clam Bay system.
Department of Environmental Protection Permit/Authorization No.:0128463-001-JC
Date of Issue:July 6, 1998
Expiration Date:July 6,2008
Project Description:This Permit authorized activities to improve the hydrodynamics of,and thus restore
and manage,the Clam Bay ecosystem.
Department of the Army Corps of Engineers Permit No.: 199602789(IP-CC)
Date of Issue:August 11, 1998
Expiration Date: July 8,2008
Project Description:This Permit authorized the following works: 1.)Replacement of Seagate Drive
Culverts and installation of one-way check valves on the culverts(pages 45-50 of the CBRMP);2.)Clam
Pass main channel dredging for Cuts 1,2, 3 and 4(pages 49-65 of the CBRMP);3.)Excavation and
maintenance of Interior Tidal Creeks(pages 65-71 of CBRMP).
Department of Environmental Protection Permit Modification for Permit No.: 0128463-001-JC
Date of Issue:February 16, 1999
Expiration Date:July 6,2008
Project Description: Authorize minor revisions to the mangrove trimming procedures pursuant to site
verification.
Department of the Army Corps of Engineers Modification for Permit No.: 199602789(IP-CC)
Date of Issue: February 26, 1999
Expiration Date:July 8,2008
Project Description:This application requested modification to: 1.)discharge dredge material from Cut#1
to new disposal area identified as an upland parking area;2.)increase the width of channel cut#4;3.)
remove native vegetation and excavate a portion of upland Disposal Site#2;4.)remove native vegetation
and excavate a portion of upland Disposal Site#3. The proposed modification to widen channel Cut#4 is
to be done without any additional seagrass impacts. Based on the review and coordination with FWS,the
permit was modified in accordance with these requests.
Department of Environmental Protection Permit Modification for Permit No.: 0128463-001-JC
Date of Issue: May 19, 1999
Expiration Date: May 28, 1999
Project Description: Re-grade beach fill material during the marine turtle nesting season to remove
pockets of fine silty material and to remove an escarpment which may interfere with nesting marine
turtles.
Florida Fish and Wildlife Conservation Commission File No.:2003-0511-016BS for Permit No.: CO-016
Date of Issue: March 24,2000
Expiration Date: n/a
Project Description:This Permit granted approval for placement of canoe trail markers in Clam Bay.
Department of the Army Corps of Engineers for Permit No.: 200001076(NW-EF)
Date of Issue: April 13,2000
Expiration Date:February 11,2002
Project Description:Approved the installation of 32 waterway markers for a canoe trail in the Clam Bay
System.
Depai latent of the Army Corps of Engineers modification for Permit no.: 199602789(IP-CC)
Date of Issue: May 5,2000
Expiration Date: July 8,2008
Project Description:This application requested modifications to the monitoring and reporting schedule
reference on page 93 (Biological Monitoring)of DA Permit(CBRMP). The request was to submit annual
reports instead of semi-annual reports. The permit was modified as requested.
Depai lment of Environmental Protection Permit No.: CO-732
Date of Issue: October 25,2002
Expiration Date: October 25,2003
Project Description:Perform dune and beach restoration,and plant salt-tolerant native dune vegetation in
association with interim maintenance dredging event.
Department of the Army Corps of Engineers Permit No.: 199602789(IP-CC)Extension
Date of Issue: May 8,2008
Expiration Date: July 8,2009
Project Description:This Permit authorized the extension of the expiration date for a period of one year.
Department of Environmental Protection Permit/Extension No.: 0128463-001-JC
Date of Issue:June 5,2008
Expiration Date: July 6,2009
Project Description:This modification extends the expiration date for a period of one year.
Department of Environmental Protection Permit No.: 11-0128463-005
Date of Issue: December 17,2010
Expiration Date: December 17,2015
Project Description: Continue maintenance activities to the hand-dug channels and mangrove trimming in
the Clam Bay system originally permitted under Permit No.0128463-001-JC.
Department of the Army Corps of Engineers Permit No.: SAM 996-02789(IP-LAE)
Date of Issue: February 8,2011
Expiration Date: February 8,2021
Project Description: Continue maintenance activities to the hand-dug channels and mangrove trimming in
the Clam Bay system originally permitted under Permit No. 1996-02789(IP-CC)
Department of Environmental Protection Permit No.: 11-0295193-004
Date of Issue:November 2,2011
Expiration Date:November 2,2016
Project Description: Install 32 canoe trail markers and informational signage.
•
Department of Environmental Protection Permit No.: 0296087-001-JC
Date of Issue:August 14,2012
Expiration Date:August 14,2022
Project Description: Restore the alignment of Clam Pass to the previously approved location and conduct
periodic maintenance dredging of a portion of Clam Pass in order to maintain tidal exchange between
Clam Bay and the Gulf of Mexico.
United States Fish and Wildlife Service Biological Opinion Activity Code No:41420-2010-CPA-0395
Date of Issue:February 22,2013
Expiration Date:n/a
Project Description:FWS analysis of the potential effects of the dredging of the Pass on the threatened
piping plover(Charadrias melodus),threatened loggerhead sea turtle(Caretta caretta),endangered
hawksbill(Eretmochelys imbricate),leatherback(Dermochelys coriacea),green(Chelonia mydas),and
Kemp's ridley(Lepidochelys kempii)sea turtles,and the endangered West Indian Manatee Trichechus
manatus).
Department of the Army Corps of Engineers Permit No.: SAJ-1996-02789(NWP-WDD)
Date of Issue: February 28,2013
Expiration Date:March 18,2017
Project Description:Dredging of Clam Pass and tidal creek to restore tidal exchange into Clam Bay.
Department of Environmental Protection Permit Modification to Permit No.: 0296087-002-JN
Date of Issue:March 1,2013
Expiration Date:August 14,2022
Project Description:Modification of August 2012 permit to re-open Clam Pass by mechanical dredging
of the Pass and flood shoal areas.
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
APPENDIX 2 - A RECENT
HISTORY OF MANGROVE
MANAGEMENT IN CLAM BAY
Appendix 2 - Recent History of Mangrove Management in Clam Bay
According to detailed field surveys performed in the early 1970's mangrove tree
densities within the Clam Bay NRPA ranged from 726 to 7,580 per acre and
maximum canopy height was 39 feet. Within the black mangrove dominated basin
forest west of Upper Clam Bay, 16% of the black mangrove trees were reported as
dead and others as severely stressed; evidenced by a high incidence of dead limbs on
trees of all sizes (Tropical Biolndustries and Gee and Jenson, 1978).
Dead and stressed mangroves were again reported for Clam Bay in 1989 when David
W. Crewz, a biologist with the Florida Marine Research Institute, was asked to
inspect Clam Pass Park by Mary Ellen Hawkins,then a Collier County representative
to the legislature (letter to Don Duden dated April 3, 1989). Mr. Crewz concluded
that the "dead and stressed mangroves were caused by lack of adequate water
circulation resulting from the closure of Clam Pass.... allowing toxin and salt
buildup."
Westinghouse Communities, Inc., employees in February 1992 noted additional
mangrove die-offs, north of Clam Pass Park on the west side of Upper Clam Bay.
This area was inspected by Dr. Eric Heald, a consultant to WCI, and reported to WCI
in April 1992, as probably due to hypersalinity, although 1991 was an above average
rainfall year. The same conclusion was reached by Robin Lewis of Lewis
Environmental Services, Inc., after an inspection in May 1994. At this time the die-
off area was approximately 6 acres. A widespread mortality of mangroves in Florida
Bay was also reported in the summer of 1991 (Yarboro et al. 1994), and it was
attributed, in part, to natural drought conditions and unusual tidal inundation
patterns.
After above average rainfall in the summer of 1995, The Conservancy of Southwest
Florida, Inc.'s staff and residents in Pelican Bay reported additional mangrove deaths
which continued through 1995 and 1996. The total area of the die-off through July
1999 was around 50 acres.
The death of trees occurred around hyper saline ponds and is consistent with conditions
caused by periods of excessive inundation of freshwater followed by periods of
continuous dry down,particularly where the mechanism for flushing is impaired. (Lugo,
et. al. 1976). During the period immediately preceding the observed die off, and during
the periods following, Clam Bay received record amounts of rainfall. This rainfall, when
combined with an admittedly impaired circulation system, encroaching development of
the Strand community to the west, and intermittent pass closure, resulted in water levels
that were high enough for a long enough period of time to adversely impact the
mangroves (CBRMP 1998).
The Clam Bay Restoration and Management Plan was finalized in 1998 to address the
mangrove die-off. In assessing a variety of alternatives to the restoration of Clam Bay,
Page 1 of 14
the original need was not so much to restore the system to at mangrove forest (although
that remained the primary goal) as it was to stabilize and resore the system as a thriving
natural resource. This was accomplished through the dredging o Clam Pass and portions
of the interior channels within the system, as well as construction of a network of hand-
dug flushing channels throughout the original die-off area and a few other areas that were
exhibiting stress. It was recognized that with changes to naturally induced flushing rates
and hydrological regimes the mangroves would likely adjust by altering zonation
patterns, species compositions,rates of growth and mortality, etc. (CBRMP 1998).
Summary of annual monitoring since the implementation of the CBRMP
Provided below is a brief, annual summary of the overall health of the Clam Bay
mangrove system. This recent history of the mangrove management spans from 1999 to
2013. These summaries include key events, such as major weather occurrences, flushing
channel construction and maintenance, as well as documentation of areas of improvement
and calculations of die-off acreages,
1999
A total estimate of 42.67 acres dead or stressed mangroves was provided by Turrell, Hall
& Associates, Inc. consisting of the main basin area adjacent to The Strand and several,
smaller, discrete areas possibly attributed to lightning strikes or where slight depressional
areas allow ponding and salinity/oxygen stress. Little change was noted later in the
summer at the time-zero survey although most mangrove plots showed significant
standing water which could be a function of the dredging work as well as tides and rains
around the survey time.
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'� �,�y.p., � s
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ff�
r JK 1�` ' 1:;5'1:''''r ' '''' ' 'L h
7
The main die-off area(NW Clam Bay, adjacent to The Strand) 1999
Page 2 of 14
2000
A full year after the dredging work, no dramatic changes were apparent, some mangrove
plots had declined; others appeared in slightly better health. Seedling recruitment was
good throughout. Heavy rains in late 1999 were thought to have contributed to a dieback
in groundcover noted by Lewis Environmental Services. No new mangrove die-offs or
expansion of stressed areas were noted. Work planned for 2001 included the
experimental Riley encasement method for mangrove propagules.
1'.1 hey"
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Main die-off area 2000
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and flushing cut
Page 3 of 14
2001
Mapping of the die-off area was repeated and estimated to have increased in size,
spreading to the north, to encompass just under 50 acres. Additionally a few new
stressed areas were identified through aerial photographs. Individual plots showed some
additional tree losses but consistent seedling recruitment. Channel construction in the
main die-off area and close to Plot 7 is thought to have contributed to the recovery
process underway,illustrated by extensive Batis and dramatic seedling recruitment.
The observations generated sufficient concern amongst project managers in 2001 that a
suggestion for additional flushing channel construction in the die off area was made.
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Main die-off area 2001
Page 4 of 14
2002
Additional flushing channels were constructed in the die-off area during late 2001 and
results from the 2002 surveys show that these efforts appeared to have been successful
with a reduction of 12 acres made in the die-off area. Batis growth and seedling
recruitment was good. The problem of exotic vegetation growth in many areas was
highlighted, and two new diffuse areas of stressed trees were identified. The presence of
standing water and bacterial mats suggested lack of flushing was responsible. The one-
way culverts installed at Seagate, thought to have reduced tidal exchange in Outer Clam
Bay, were removed in October to determine whether tidal exchange between Venetian
Bay and Outer Clam Bay could be achieved without affecting Clam Pass.
1
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Main die-off area 2002 with notable re-growth
Page 5 of 14
2003
Stressed areas identified in 2002 were revisited, and no changes were noted in 2003. One
of the.aerially depicted mangrove stress locations was found, upon groundtruthing, to
actually be an infestation of exotic plant species. Of significance is a reduction in
calculated die-off area to just over 17 acres total with 14 acres in this main die-off region,
now classified as recovering.
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Main die-off area 2003
Page 6 of 14
2004
Die-off acreage was estimated at 18 acres total in 2004, with the addition of a new area
adjacent to the Contessa condominium building in Bay Colony and several new small
lightning strike areas throughout the system. Plot 7 continues to show the most dramatic
change of mangrove plots where most exhibit slow change in existing tree number, some
losses, some growth and size-class change, but consistent seedling recruitment. Storm
events in 2004 (Charlie, Frances, Ivan, and Jeanne) had minimal effects with some leaf
loss and limb breakage. Additional flushing channels were constructed during dry season
of this year. Water level monitors put in place last year were removed due to repeated
equipment failures.
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Main die-off area 2004
Page 7 of 14
2005
Several stressed areas were noted as recovering this year including that adjacent to the
Contessa building where a drainage channel was in need of maintenance and clearing,
work which alleviated the problems. A new die-off area was identified near the County
boardwalk and it is suggested that clogging of channels due to Hurricane Charley maybe
responsible. Total die-off acreage in 2005 is estimated at 24.7 acres. Plot 7 and Plot 8
continue to show significant re-growth.
Hurricane Wilma in October of 2005 caused considerable leaf loss, limb breakage and
leaf browning throughout Clam Bay although the constructed flushing channels alleviated
extensive ponding that could have occurred, and the system weathered the storm well.
Work completed in 2005 included the last component in flushing channel construction.
In total, approximately 13 miles worth of hand-dug channels have been installed since
1999.
s xrF e`
Main die-off area 2005
page 8of14
2006
Stress damage from the 2005 hurricane season necessitated the need for a division of the
classification system currently used to define the status of the mangroves in the system.
Stressed mangrove zones are now classified as "die-off area" for mangroves stressed by
some factor other than storm events or"area of concern" for mangroves stressed by storm
events. It was estimated in 2006 there were 23 acres of recovery, 12.3 acres of stressed
areas of concern and 23.4 acres of die-off area present, bringing the total area of stressed
mangroves to 74.7 acres. Since the last mangrove channels were dug in 2005 and
dredging work continues when needed, most of the monitoring plots have shown
improvements and there has been a significant reduction of die-off in the original locale.
:.
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:, :fi+c3 '# fi ,g g ..>x';Y 'A',r3.• i'S '<{ 'a a, ,s'*S1t.•$ s': t?#.'- 17' `ICT
fr
r;L:#1;?.:140.tteftitfi'.:50444,!,..,,14‘,105:"c'r.:;.,
yt
Main die-off area 2006
Page 9 of 14
2007
The storm damage of 2005 added a level of difficulty to subsequent classification of areas
within the system. Extensive defoliation and falling of individual trees meant that areas
that could be termed stressed by til-;,_,--
he flow issues thought to have been responsible for the
original die-off in Clam Bay were in fact affected by the high winds and storm surge.
Approximately 4.9 acres of formerly classified `die off area have been reclassified to
`recovered' this year. Stressed areas of concern that are likely not related to storm
damage total about 15 acres while areas of concern that we suspect are due to the •
storm
events have been estimated at about 25 acres. An additional 20 acres within the original
die off area has not yet fully recovered and is also included in this category. A total of
10.6 acres of mangroves are still considered dead, a significant reduction from the
original die-off of over 50 acres in the late 1990's. This brings the total aerial estimate of
mangroves that are not at optimum health to about 70 acres.
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F yr,,.}r{ ;4T ;,•:F-'4
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Main die-off area 2007
Page 10 of 14
2008
The 2008 monitoring report was the final report associated with the original 1998
restoration permits. Effects of the storms form 2005 still added a level of difficulty to the
classification of areas within the system. While the defoliation associated with the storms
had mostly recovered, falling debris affected several of the monitoring plots throughout
the system.
Approximately 35.4 acres of forest area have been removed from the die-off
classification since the implementation of the project. Stressed areas of concern that may
still be related to storm damage total or may be due to other factors (such as ponding or
drying) add up to about 7.1 acres. Areas throughout the system that have not yet fully
recovered but that have flushing channels and have shown marked increases in mangrove
recruitment and new growth have been removed from this category(approx. 20 acres).
A total of 7.3 acres of mangroves are still considered dead. This includes three main
areas, the initial die-off area east of the strand where there are about 5.5 acres still dead,
the damage from a tornado in the extreme north of the system accounts for about 0.8
acres, and the Hurricane Charley damage that resulted in a tidal restriction just south of
the Pass accounts for about 0.75 acres. Several lightening strikes and small discrete die-
offs spread throughout the estuary make up the remainder of the die-off acreage.
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t "a f ;` �" � T; ria • i l;S` t'
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r y
t J 1.','
East of the Strand Die-off area, 2008
Page 11 of 14
2010
Even though the permit requirement for monitoring reports ended with the expiration of
the 1998 permits, the PBSD continued to monitor the mangrove health within Clam Bay
and document the positive results within the mangrove forest. Exotic eradication
activities were also continued to allow for natural regeneration of mangroves observed
elsewhere in the system.
Construction of the last component of the flushing channels was completed in the 2005-
06 season. Inspection of these flushing cuts this year showed that they are still operating
as designed and are contributing to the continued growth of new mangroves within the
system.
Stress in mangrove forest areas is still apparent, although in several areas this may still be
attributable to storm damage or to frost damage brought about by a couple of very cold
temperature nights. The spectacular recruitment of white mangrove seedlings, now 8 to
10 feet tall saplings, throughout the original die-off area is testament to the efforts
undertaken with the initial dredging and that work can be considered a success.
t
. ,,,,..._.,..e,xit .,, i ., . , , . _..,,, x : : . , , ,., „. ,
Main die-off area 2010
Page 12 of 14
2011 -2012
An infestation of boring beetles was discovered in the early months of 2011.
Observations within the system and research into the life habits of many boring
beetles led to the conclusion that white mangroves stressed by the sustained cold
temperatures in December 2010 and January 2011 were most susceptible to the beetle
attack. Cold stress reduced the abilities of these trees to fight off the boring activities
and many trees succumbed to them. Yellowing leaves, leaf drop, and eventual death
of the tree was the result. The dead trees were easily visible in the rooftop photos
taken periodically from the Grosvenor and Montenero condominiums. Efforts to
hatch beetle larva led to the identification of at least two species, around-headed
(Longhorned beetles) and aflat-headed borer (Metallic beetles). No further loss of
trees was documented after 2012 as a result of the borers.
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.„.,..,.:„ . „....., : ._..,. , :, ,,,,....„..,, „:„...,:- ..,,,,.
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..,;„..,,.„,„_-,• v. -A .. .-s- ":'*--:,...'",-. %.0-1k -...-:,,-,x,;-.,t
;1. 1 : .u4s'r=�� . m r Sh q.+r`.j-.,-"ger '• rh i .r
(y`.--,,31'''''.4. : i�.s F,.,* :Y wt i �i f .,,i: '' Bw.1` , .r r} .`.
3"i ,,,F� t y i f �!� F �,.j,111,,,-aa_ _.•'.ar ''fi^"•.
u� f t
White Mangroves affected by cold and borers
�. I s Orotit
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viz.
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Borer damage to stressed tree
Page 13 of 14
2013
The lack of harsh weather occurrences, hurricanes or freezing temperatures over the past
year seems to have allowed the areas impacted by the boring beetles to begin to recover.
A total of 4.02 acres of mangroves are still considered dead or stressed, a significant
reduction from the original die-off of over 50 acres in the late 1990's. Typical flushing
channel maintenance was conducted to ensure that the channels were operating as
designed and continue contributing to the growth of new mangroves within the system.
J t
4
r o-'
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1 4
Main die-off area 2013
Page 14 of 14
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
APPENDIX 3 - RECENT HISTORY
OF SEAGRASS PRESENCE IN
CLAM BAY
Appendix 3 - Recent History of Seagrass presence in Clam Bay
Reports of field surveys from the early to mid 1970's document the presence of
seagrasses within the Clam Bay NRPA but do not give any estimation of coverage or
densities within the system. It is noted that seagrasses are present only in Outer
Clam Bay, and there is some hypothesizing that the lack of seagrasses in Inner and
Upper Clam Bays is the result of lower salinity levels and lack of water exchange
with the Gulf. (Heald, 1972, Tropical Biolndustries and Gee and Jenson, 1978).
The Collier County Department of Natural Resources produced an analysis of the
seagrasses and benthic infauna in Clam Bay in 1987. In this report it is stated that a
15m x 15m plot encompassed most of the grass beds in Clam Bay. The report
exhibits show the plot location on the east side of the waterway between the Pass and
Outer Clam Bay,much in the same location of seagrass beds which exist today.
A DNR memorandum.produced by David Crewz in 1989 also mentions "some
seagrass and algal beds" being present in Outer Clam Bay but again offers no
information on location, aerial extent,or densities.
The 1991 Collier County Seagrass Protection Plan states that "Outer Clam Bay contains
one of the densest and most extensive seagrass beds in Collier County," though it does
not quantify aerial extent or density within the report. An exhibit associated with the
report shows the entirety of Outer Clam Bay from the Pass to the Seagate culverts as
seagrasses(almost 60 acres).
A 1994 report documenting conditions in the proposed Clam Bay Natural Resources
Protection Area by the Collier County Environmental Services Division documented that
seagrass coverage in Outer Clam Bay was approximately 10 acres.
Based on anecdotal information and on comparisons with other seagrass areas in the
County during the same time frame, it is not presumed probable that there was an 80%
decline in seagrass coverage during those two years but instead the 1994 report may have
over-estimated the coverage.
In 2007,PBS&J conducted a seagrass assessment in Outer Clam Bay for the Collier
County Coastal Zone Management Department. Of the 30 randomly selected sampling
sites observed,seagrasses were found in 13 of them. No conversion to an acreage
estimate was made in this report. At the locations where seagrasses were observed,the
estimated density relative to bottom coverage was between 5 and 25 percent.
Annual Estimates of Seagrass Coverage since implementation of CBRMP
Page 1 of 7
The following annual summaries provide general observations of the presence of
seagrasses within Outer Clam Bay since the implementation of the Clam Bay Restoration
and Management Plan.
SEAGRASSES APPROX.10.04 AC.
',Ailipr-.-: -;:'''--''''''':'-'' ' ''',:/;`:;-',...ii-:-Y,)., ',.- i i-2.,i.,.'. '",-=. ..,.:/-1,.';'-':?..1;:ri;''':-..V.:-'''-',,, '.;-'.'-':-.. .,-*
g
1,-
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—._ , sR s r kc i4 i�, s z'r tai
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�x�[{ .jt S� 15i i�Fci n yj i,1!; ., 4-:Ps--...v..---- 1 r "Y ��'.'i �1. i ;e, 4 31 ,
v Itt
; i:;,..,....,....:....,...,,..1.1.,,. 4 • ...T i ,,,-. ;. I,., 3,..,1., i I/4e "t-r,,, I pc..-;„if.;, ... ,',..,1,1 -.':
.' t•q 1W V:Ml • ''•••:',17. ,.-.4. 0 t1-144'
U . ',s '' P ., ,14'1.0;. \s�f t• y_,..
r i'� h:lQ {Y .2 �- r!. -e &1�f¢,ry ::1!!';',1.t .--1, ,* tkk44T ' s'�e
i NIi' '4 4 1'4•t_7 7's ',,.. scv °-31_1 W`r''';')---1:. •; ,111,a��'43i tr - ?` —r(_i:,
Approximation of 1994 Seagrass Coverage
Page 2 of 7
1999
Prior to the initial dredging associated with the 1998 restoration and Management Plan,
seagrass acreage is estimated at 5.13 acres, restricted to Outer Clam Bay and the channel
leading to Clam Pass.
I
i
I
0SEAGRASSES APPROX.5.13 AC
I
L. k k
S
s.17
P xis£ ''$ $ i.!>' }' ts., '' t S ,,k":* ,,y ,ti
; Is
� " " , r
�
� 1 � � 5k "R i44�_ � 4
i.--...F, f. �t � �t::ya�; �� l il `iF� -� 5a�� �
��`-,_„,-31-410,,,,
r: \� }t
+ 3 y, L : F s : 4l \' F '�
t„ ,1-1-..;,, ,,--,-,(7,,
44- f ~
� � MI .�{ � ! � • xk
sil41_��i� _�1�1� ht,'i. _�'i\�C . �� 4as �d� c.f
_401_�trASca!'*1f
1999 Seagrass Coverage
2000—2004
Seagrasses show a slow decline during this time frame. Water quality testing within the
system does not indicate chronic degradation. The decline is attributed to the increased
tidal range caused by the dredging work, which results in longer exposure at low tides of
the shallow areas where seagrasses were present. The one-way culverts installed at
Seagate, thought to have reduced tidal exchange in Outer Clam Bay, were removed in
October 2002 to determine whether tidal exchange between Venetian Bay and Outer
Clam Bay could be achieved without affecting Clam Pass. Seagrass bed in southernmost
portion of Outer Clam Bay begins to expand in 2003 after removal of flap gates.
Page 3 of 7
2005
An increase in the seagrass coverage within the channel transects was documented.
Increased density of the beds within the bay area east of Clam Pass is also noted.
2006
Shoal grass patches are still present in ecologically significant densities within the
channel north of the County boardwalk and just inside Clam Pass mouth. Sea grass beds
in Outer Clam Bay are still reduced compared to the 1999 pre-dredge conditions, but
their steady improvement since 2004 seems to have continued into 2006. Approximately
3.6 acres of seagrasses are not
along the transects.
SEAGRASSES APPROX.3.62 AC.
'.a. •,..40*''
xaJ' "'IS
AN.
r_
, ,_,,,,,,, I. . . ,
,i'sic.„.„4„1 ,...„.,.
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P L
(3 4
4it
ti,- ''' - ce'C;'e l s `-�€ �3 �-, •b '- `iU r X:.L ` c4 4 ",}'4�3 n
' `I ` 3R - i' t* ` - 1c ,
w 1�• �' �'rtit r S L' •;1 o 't T`'r , sem
vp.
t yV:-.',4-.' -----f- .- 3,„:-(, :,,-,,,,.6-c. v.;„:_y .,_ ,„...,...1 <.1,41,,;,c_s_ 4,..._. .,.,-
r. 1. • '- 'L-•....f.rt 4e i;:,kr....Pit.P /1"..'„W,'...aniiiimuniLki:144.......,_,.... •
2006 Seagrass Coverage
Page 4 of 7
2007
Concerns related to the seagrass coverage within the bay were raised by adjacent property
owners this year, and Collier County contracted an additional study by Post, Buckley,
Schuh, & Jernigan Inc. (PBS&J) to investigate seagrasses and nutrient inputs within not
only the Clam Bay System but also Venetian Bay, Moorings Bay and the entire Doctors
Pass area.
Some of the results of the PBS&J study relevant to the Clam Bay System were;
• That seagrasses were present within Outer Clam Bay. Paddle Grass (Halophila
engelmannii) was observed at 13 of the 30 randomly generated points within
Outer Clam Bay.
• That residents' concerns that seagrass coverage had declined from 60+ acres to
present were unfounded as early estimates of 60+ acres were likely erroneous.
• That nutrient and chlorophyll-a levels within Outer Clam Bay had increased over
the past 20 years but were still below median values for Florida estuaries.
Also as a result of these increased concerns regarding seagrasses, Turrell, Hall &
Associates expanded the annual seagrass survey to cover the entire bay and not just the
defined transects. Additional seagrass beds and macroalgae were observed in areas
where they had not previously been documented. Though all of THA observations were
of shoal grass, it was noted that all of the PBS&J observations were of paddle grass. It
has been observed in the past that paddle grass is very ephemeral in this system and it is
likely that the 2 months between the PBS&J and the THA surveys was enough time for
the paddle grass to disappear.
2008
This was the final monitoring event of the seagrasses associated with the 1998
Restoration and Management Plan permits.
Increases in seagrass coverage that were noted in 2007 continued through this year. A
small area of paddle grass was observed along Transect #2 which had been devoid of
grasses in the past. Other transect areas that have been devoid of grasses until this year
include the western shoreline of the channel between Clam Pass and Outer Clam Bay
(Transect 5). Seagrasses had been present along this area prior to the dredging but were
replaced by black mangrove propagules when the increased tidal range led to extended
drying times of the shoals where the grasses had been located. New grasses this year
have been observed along the edges of the channel in areas that do not dry out so much
during low tides.
In addition to the seagrasses, other observation made along transects indicate that the
biological diversity of the macro-invertebrate fauna within the system has increased.
Page 5 of 7
Several mollusk species, including Florida horse conchs, southern hard clams, stiff pen
shells,tulip snails, cockles, oysters, and several others were all observed.
2012
Seagrass coverage within Outer Clam Bay has continued to increase. The initial decline
noted immediately following the initial (1999) dredging activities appears to have been
reversed over the past 8 years. The decrease stabilized around 2004 and has reversed in
the past few years to where the grass beds are re-establishing previous areas and new
areas appropriate for the grasses (in terms of water depths and light penetration) are being
colonized. Approximately 4.27 acres of seagrasses were noted within the system this
year. Most of the seagrass observed was shoal grass though small patches of paddle grass
and turtle grass were also observed. Future monitoring of the seagrasses will be
conducted to see if this trend continues.
SEAGRASSES APPROX.4.27 AC.
i 4- f--
� �,� -,fit:9 f" ,N %)
tom _
t`,``.
\• tt- -x - o
F`--,1s, ... ,, ^6 , * ,,rte�+
•r ' `tLk. I�I X
_``�. 4�s�1'r`_ + tc'„(',. - 7r'
,_ -1„.,,,,,4.4...-:- t: 0 - ' coot —' -,f! '.1 _ . ,.'.4 p .” J--. - '-'1,-.1-1. , s
41,
( '1i,; . '.i ,,,. „„, , aid i -- \ 'J
ikATN + " , r ..qtr=,/,
2012 Seagrass Coverage
Page 6 of 7
2013
Seagrass coverage overall totaled approximately 2.85 acres along the monitored transects
within the Clam Bay system. What has been shown by the past thirteen years monitoring
is that there was a decrease in the monitored seagrass beds immediately following the
initial (1999) dredging activities. This decrease appears to have stabilized around 2004 or
2005 and has reversed in the past few years to where the grass beds are re-establishing
previous areas and new areas appropriate for the grasses (in terms of water depths and
light penetration) are being colonized. Future monitoring of the seagrasses will be
conducted to see if this trend continues.
• f ..
'` "f 1-0r3 ' '.{�
\1
iA'+"9 II, r .t �„ _ _
,. , ;i';'
. V.:-Silt,' . :,, ','. =; ..--' ',,-',;1;:::,.,,,, '-,...,7_;$.: ..'-',--;::;‘,.`,-,-r;;,,',.,,, -'2.: '' ,_,- gel „,...,,4,,
6
,.2..,, ...„--. --,., . . ,,_,,..., ‘,,,, , .,„,„,....,,,. ..,,..:,_:-.;,. ,, „.,,,..,_
:_, _ ,,,r, .4 As.ii. ,‘ i le ..,,,,s V.4--, 44 ,,,y,_,1,. ,..-... c,t..7-zi c.°__.„---, 44
iz, .• ' o' 1 .-•'.1,4, 111k ' A1;4' . •- k .,, — _ ,....A ....,,,... ,,,,,,(4,_
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2013 Seagrass Coverage
Page 7 of 7
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
APPENDIX 4 - PHYSICAL AND
NATURAL RESOURCES
Appendix 4 — Physical and Natural Resources
Soils
Based on the National Resource Conservation Service(NRCS)"Soil Survey of Collier County
Area, Florida" (NRCS, 1998)there are 2 different soil types(soil map units)present within the
NRPA boundary.
It is important to understand that where the soil survey shows mapping units named for soil
series,the units represent the dominant undisturbed soils in that landscape that existed
predevelopment. The unit descriptions do not recognize or appropriately interpret the drastically
disturbed nature of urban landscapes created after the soil survey was completed.
Durbin and Wulfert mucks,frequently flooded(Map Unit#40), covers approximately 66%of the
NRPA. These level,very poorly drained soils are most often found in association with tidal
mangrove swamps. Mapped areas can consist entirely of either Durbin or Wulfert or any
combination of the two soils. Individual areas are elongated and irregular in shape and range
from 50 to 1000 acres. The slope is 0 to 1 percent. The permeability of the Durbin soil is rapid,
and the available water capacity is high. The permeability of the Wulfert soil is rapid, and the
available water capacity is moderate. The water table fluctuates with the tide and is within 12
inches of the surface most of the year. The soil is subject to tidal flooding. The natural
vegetation within these areas consists of red,white and black mangroves.
Canaveral-Beaches Complex (Map Unit#42) covers approximately 9 %of the NRPA.
This map unit consists of the nearly level,moderately well drained Canaveral soil on low ridges
and beaches. Individual areas are elongated and irregular in shape and range from 20 to 300
acres. The slope is 0 to 2 percent. Typically,beaches consist of sand mixed with shell fragments
and shells and are subject to frequent wave action. The permeability of the Canaveral soil is
rapid to very rapid. The available water capacity is very low. In most years,the seasonal high
water table is at a depth of between 18 to 40 inches for 1 to 4 months. This soil is subject to tidal
flooding under severe weather conditions. Natural vegetation consists of sea oats, seagrape,
cabbage palm, and salt grasses. They are commonly invaded by exotics such as Australian pine
and Brazilian pepper.
Topography
Topography is shown below using a Light Detecting and Ranging map (LIDAR) obtained from
Collier County. The elevations within the NRPA boundary range from+5.0 to -7.0 NAVD88.
The surrounding lands are generally higher than the NRPA and generate the freshwater flows
into the preserve(see attached Exhibits).
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LIDAR map of the Clam Bay NRPA
Climate
Clam Bay's climate falls within the United States Department of Agriculture(USDA)
subtropical classification. There are essentially two seasons experienced. The wet season occurs
in the summer, and the dry season occurs in the winter. Typical rainfall and temperature data are
provided in Tables 1 and 2.
In the summer the center of the trade winds shift north and moisture-laden breezes blow from the
east or south-east. In winter the trade winds shift southward and the winds are less constant.
Weather is then more influenced by fronts advancing from the northwest. This brings cooler
conditions, although temperatures rarely reach freezing, due to the fact that they are being
moderated by the surrounding waters. Cold fronts are typically preceded by winds from the
southwest, which clock to the west then northwest as the front passes,with strong winds of 20-25
knots and cooler air. In general terms,winds are predominantly southeast during the summer
and northeast during the winter.
Historical meteorology for Clam Bay is based on data collected for 30 years (from 1981 to 2010)
from Naples Municipal Airport by the Florida Climate Center(NOAA&FSU). The following
charts present meteorological statistics for temperature and precipitation.
1981-2010 Temperature and Precipitation Normals Graph
110.0
100.0
90.0s .610,0"" ia—• i.�.�„�
80.0
��� r�! �+��„8 � `•
r"'�,# s(y4r�
▪ •
70.0 • v.,.,�..� i + 'a i,..�S �,.,� * �
130.0 �, �'�'��
50.0
40.0
30.0
20.0
10.0 ,, —�.W r„„,„,..0. � r ay•
0.0 •��, ���'- �
Jan riar May Jul Sep Nov
o Precip (in) 0 Min Tmp (T) 0 Avg Tmp('F) 0 Max Tmp CF)
Temperature
The monthly average temperatures range from 64.5°F to 83.2°F. The lowest monthly minimum
temperature is 54.2°F while the highest monthly maximum temperature is 91.2°F. The data
reflect a humid subtropical climate with a narrow fluctuation in air temperature.
Precipitation
Average annual rainfall for the Naples Municipal Airport NOAA station is documented at 51.89
inches. The data in the table indicate the highest rainfall occurs during the summer months of
June, July,August, and September.
1981-2010 Temperature and Precipitation Normals Graph
0 Precip(in) 0 Min Tmp(°F) 0 Avg Tmp(°F) 0 Max Tmp("F)
January • 1.85 54.2 I 64.5 74.7
February 2.10 56.8 66.9 76.9
March 2.38 60.0 70.0 79.9
•
April 2.36 63.4 73.3 83.2
May 3.16 68.5 78.2 87.8
June 8.82 73.9 81.9 89.9
July 7.27 74.9 83.1 91.2
August 8.58 75.3 83.2 91.0
September 7.69 74.8 82.4 89.9
October 4.19 70.0 78.5 86.9
November 2.04 62.9 72.1 81.2 .
December 1.45 57.0 66.876.6
Winds
Winds are predominantly easterly throughout the year,but with a tendency to become
northeasterly from October to April and southeasterly from May to September. Winds speeds,
not including storm events are, on average,below 10 knots. During the winter months when
fronts move through for a day or two at a time, winds out of the northwest to northeast may
increase to about 25 knots.
Sea breeze
As the land surface around Naples and Clam Bay warms,the air above is heated. The warm air
is less dense and tends to rise creating a lower air pressure over the land than the water. The
cooler air over the water then flows inland creating a sea breeze. In the evening the reverse
occurs and the cooler air over the land will flow back toward the water creating a land breeze.
The incoming sea breeze acts as a lifting mechanism,resulting in the warmer air rising up to
higher altitudes. This creates cumulus clouds that begin to build which leads to the development
of afternoon showers and thunderstorms in the area.
Storms
Naples and Clam Bay specifically are within the Atlantic Tropical Cyclone basin. This basin
includes much of the North Atlantic, Caribbean Sea, and the Gulf of Mexico. On average,6 to 8
tropical storms form within this basin each year. The hurricane season lasts from June 1st to
December 1st. The formation of these storms and possible intensification into mature hurricanes
takes place over warm tropical and subtropical waters.
SaHir-Simpson Hurricane Scale Eventual dissipation or modification, averaging 7 to 8 days
Category Wind speed Storm surge later, typically occurs over the colder waters of the North
mph ft Atlantic or when the storms move over land and away from
( ) (m)
the sustaining marine environment.
7-711Five
� r (>5.4]
131-155 13-18 Due to the destructive nature of these storms, landfall can
Four (210-249) (4.0-5.5) result in significant damage to upland development and
Three 111-130 9-12 facilities from storm surge, waves, and wind. A good example
(178-209) (2.7-3.7) of this would be Hurricane Wilma which formed in 2005.
Two 96-110 6-8
(154-177) (1.e-2.4) A tropical storm is defined by maximum sustained winds from
11 One 74-95 a-5 35-64 knots(40-74 mph). A hurricane has maximum
(119-153) (12-1.5)
Additional classifications sustained winds that exceed 64 knots(74 mph). Hurricanes
are classified into different categories according to the Saffir-
,. -- Simpson scale. Hurricanes can also spawn severe weather
such as tornadoes as they move inland.
The table below lists the number of tropical storms and
hurricanes that passed through or near Naples over the past 20 seasons including 1992 through
2012 as reported by the National Oceanic and Atmospheric Administration(NOAA)Coastal
Services Center and Hurricane City(www.hurricanecity.com). Analysis of the available
information indicates that Naples, on average, is brushed or hit by a tropical storm or hurricane
once every 2.71 years and is directly hit once every 7.05 years.
Table 3 Number of Named Storms Passing through or near Naples
Year #of Storms Names Strength closest to Naples
1992 1 Andrew Hurricane Cat. 3
1993 0
1994 1 Gordon Tropical Storm
1995 1 Jerry Tropical Storm
1996 0
1997 0
1998 1 Mitch Tropical Storm
1999 1 Harvey Tropical Storm
2000 1 Gordon Tropical Storm
2001 0
2002 0
2003 0
2004 1 Charley Hurricane Cat. 3
2005 1 Wilma Hurricane Cat.2
2006 0
2007 0
2008 1 Fay Tropical Storm
2009 0
2010 0
2011 0
2012 0
2013 0
Hurricane Wilma image
10/19/05 12001 24L RILMA -
10/19/05 13451 GOES-12 WV
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Waves
Clam Pass connects the Clam Bay system to the Gulf of Mexico's tidal water fluctuations and
open coast wave energy. Clam Pass is subjected to relatively low wave energy. Significant
wave heights in deep water commonly range between 1 to 3 feet(0.3 to lm). Predominant wave
directions are from the northwest to west, especially during the winter months,while summer
and tropical storm events include wave energy from the south and southwest. The beach
material is composed of fine sand having an average median grain size of 0.2 mm. The average
net sediment transport along the southwest Florida coast is approximately 30,000 to 60,000 cubic
meters per year to the south. The relatively small tidal prism for Clam Bay provides a critical
balance between tidal flow in and out of the inlet channel and littoral processes moving
alongshore. This affects the inlet hydraulic efficiency over time, especially when littoral
transport rates are high due to periods of high wave energy.
The wave climate at Clam Pass was obtained from the NOAA Wave Watch III (WWIII)model.
Wind and wave data were extracted at the nearest station, located approximately 2 miles offshore
of the Pass. The data included significant wave height,wave period and direction, as well as
wind direction and speed. A total of 8 years of data were extracted from the beginning of 2006
to the end of 2013. Figure 5 shows the wave/wind roses for the 8 year record. The wave and
wind rose graphs show a color coded percentage of occurrence in wave height or wind speed in
incremental direction bins of 12.5 degrees. The wave direction notation is where waves are
originating from,while wind direction is where it is heading. The combined annual wave rose
shows that largest waves and highest frequency waves typically originate from the northwest to
west direction. Because the annual wave rose does not describe seasonal variations,the wave
data of 2013 were evaluated monthly and represented by wave roses to assess variations in wave
energy direction. Figure 6 shows comparisons of the monthly wave roses for the 2013 data
indicating the temporal variation in the incoming waves during the winter and summer months.
WAVE ROSE WIND ROSE
Nun NNE NNW f•
NNE
JS 21S• arts vs
ies
ern NE Uti
NE
•E fi ns"/ , �.
Wry13.1
E l ENE
•
0.
IE
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5.0
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�•� � Mrs rwf
NSW
we 00E MY EEE
E
".' - E; Z m a
"Te.�1Fn Ori
....14.,...OW
11s41
Figure B3. Clam Pass,Wave&Wind Roses-2006
Wind and Wave Roses—2006-2013(Provided by Humiston and Moore)
WAVE ROSE WIND ROSE
N
N
Wrfr
l•
NNE NNW E NNE
lir S' i:i' SNS• us.
NW" fr NE NEI /�r^'d� NE
NE `\ NS• r9'f M1' fi•
/ ;
rx WNW ENE
s r//;: r.E Ei3• :CS• OW Ery•
Pfr
41.
W .0 Ll W° r W .r. SE 4 • r
SA
WSW \ t.. EEE WSW)E• illi ESE
88W
1M. AEE In.
30.3• .57 S.
0 SSW SEE
S
0 02 03 01 05 06 00 1 0 2 4 0 0 10 12 10 45
Wa+o Ili 011(n) Wir3 Speed Inds)
1-, 1i .,e figure 2.Clam Pass,Wave&Wind Roses—2006 to 2013
l Wind and Wave Roses—2013(Provided by Humiston and Moore)
Natural Communities
In this Section, a natural community refers to the mix of plant and animal species that form the
natural basis of the Clam Bay NRPA. A combination of factors including geology, climate,
hydrology, soils, and anthropogenic influences determines the specific types of plants found in
any given area. These plants are a major factor in what type of animal species that may be
present. The Florida Department of Transportation's Land Use, Cover and Forms Classification
System(FLUCFCS 1999)has been used to identify the plant communities found within the
Clam Bay NRPA. See the attached Exhibits for an overall FLUCFCS map of the Clam Bay
system and the existing monitoring plots within these habitats.
Table 4: List of FLUCFCS Communities within the Clam Bay NRPA
FLUCFCS Community Description Upland or % of Clam Bay
Code Wetland NRPA
181 Swimming Beach Upland 5.95
186 Community Recreation Facilities Upland 0.40
322 Coastal Scrub Upland 3.97
428 Cabbage Palm Hammock Upland 0.45
540 Bays(with and without direct Wetland 23.16
connection to Gulf or Ocean)
612 Mangrove Swamp Wetland 64.60
642 Saltwater Marsh Wetland 0.04
651 Tidal Flat Wetland 1.43
911 Seagrasses** Wetland 0.84**
**included in the Bays(541)category
Several other components of the Clam Bay NRPA ecosystem are also addressed below. These
components include offshore hardbottom,oyster, and other benthic faunal communities that are
not specifically addressed in the FLUCFCS classification system. Additional historical
information on the Clam Bay mangrove and seagrass habitats is included as appendices to the
Management Plan.
FLUCFCS Code 181-Swimming Beach
Beaches form when offshore sand deposits are moved landward by wave action usually during
the spring and summer. Sand,which is stirred up as the wave breaks on the shore, drops out of
suspension as the water moves up the beach face. Thus,the beach becomes gradually higher,
wider, and steeper. In the wintertime,larger,higher energy waves associated with winter storms
overflow the beach area and stir up the sand deposited earlier in the year. The sand is pulled off
the beach as the wave recedes and is deposited in an offshore sand bar. If these two forces are in
equilibrium,the beach area will be stable from year to year. However,naturally occurring
factors, such as storm events,littoral drift(lateral movement of sand because waves approach the
beach at an angle), and offshore winds,upset this equilibrium and result in the ever shifting
nature of the beach environment.
-�
Dunes form because of onshore wind action on beach and sand. When wind speeds are
sufficient,individual grains of sand start to roll and bounce along the surface. This windborne
sand is transported landward until the wind speed drops below that needed to move the sand.
Coastal vegetation is critical for slowing wind speeds and causing sand to be deposited.
Landward of the highest tides,pioneer or frontal zone sites are stabilized by sand trapping action
of various rhizomatous grasses and low growing shrubs that are tolerant of salt spray. Only a
few plant species can tolerate the stresses of a dune environment,particularly frontal dune sites.
Foredune plants must be able to survive being buried by blowing sand, sand blasting, salt spray,
and saltwater flooding, drought,heat, and low nutrient supply. Coastal plants colonizing the
dunes are key players in trapping windblown sand and preventing coastal erosion as the first
defense against heavy winds and surge of tropical storms.
Many plant species that occur on dune areas have developed specific attributes to help them
survive these harsh environments. These include high growth rates,dense root systems,low
profiles,and high flower and seed production rates. Species common on the beaches of the Clam
Bay system include: sea oats(Uniola paniculata), seagrape(Coccoloba uvifera),and railroad
vine(Ipomoea pes-caprae).
FLUCFCS Code 322—Coastal Scrub
Landward of the frontal(beach) zone area is the back dune zone(also often called the coastal
shrub or scrub zone), a portion of the dune that is more stable,has greater organic matter, and
supports less salt tolerant grasses and shrubs as well as some trees.
Many of the woody species found in coastal scrub are low growing and shrubby due to low
nutrient and droughty conditions of sandy soils. High winds and salt spray often prune the
terminal buds of the trees and shrubs growing on the dunes and result in salt-pruned,windswept
canopies.
Coastal scrub is represented by a conglomeration of coastal species generally found in a narrow
band between the mangrove forest and the beach areas. Species common in the coastal scrub
zone of the Clam Bay system include: seagrape(Coccoloba uvifera), cabbage palm(Sabal
palmetto),buttonwood(Conocarpus erectus) and Spanish bayonet(Yucca aloifolia). This is an
important habitat as it helps anchor the back dune sands and provides habitat for several listed
plant and animal species including the gopher tortoise(Gopherus polyphemus). See page 52 for
a more complete list of plant species found in this habitat.
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FLUCFCS Code 428—Cabbage Palm Hammock
This forested zone is composed of the more protected dune vegetation farthest from the Gulf of
Mexico. The Cabbage Palm Hammock habitat is identified by the preponderance of cabbage
palms (Sabal palmetto). It is generally found in pockets located between the mangrove forest
and the coastal scrub zone or beach areas. Aside from the cabbage palms, seagrapes(Coccoloba
uvifera),buttonwood(Conocarpus erectus), and several other hammock species, such as wax
myrtle(Myrica cerifera) and myrsine(Myrsine guianensis), are common. See page 52 for a
more complete list of common plant species found in this habitat. A hammock is a habitat that is
densely shaded by a canopy of trees. Hammocks usually have sparse groundcover that leaves the
forest floor mostly open for animals to travel through. Hammocks also provide a reprieve from
the sun for animals and humans alike. In Clam Bay, this habitat is also susceptible to infestation
by exotic vegetation, such as Australian pine(Casurina eguisetifolia) and Brazilian pepper
(Schinus terebinthifolius)which are addressed later in this Section.
FLUCFCS Code 510 and 540—Interconnecting Creeks and Bay(with and without
connection to the Gull)
The Clam Bay NRPA contains the three larger bays associated with Clam Pass(Outer,Inner, and
Upper) as well as the interconnecting shallow creeks and small open water areas. Second in
extent of aerial coverage within the NRPA boundary, it is the bays and interconnections which
serve as the life blood of the estuary.
These open water habitat serves as the basis for many other communities. Seagrass beds,oyster
bars, clam beds, and other benthic communities can all be supported to varying degrees with the
open waters of the bays and interconnecting creeks. As outlined below, several of these
communities are present within the Clam Bay NRPA and will be considered when deciding on
management activities outlined within this Management Plan.
Multiple studies have indicated that the single most important thing that can be done to restore
the health of the Clam Bay system is to improve the total tidal flushing capacity of the system
(Tackney 1996; Lewis 1997;Wilson Miller, et al 1996;Turrell 1995). The dredging conducted
within the Pass and the interconnecting creeks, as well as the hand-dug flushing cuts,have been
seen as the major contributing factors to the restoration of the mangrove forest community within
the system(Turrell 2008; Humiston&Moore 2003).
Tidal Pass
Clam Pass is the only open water connection to the Gulf of Mexico for the Clam Bay NRPA.
The exchange of seawater between Clam Bay and the Gulf is critical to the ability of the estuary
to export organic matter, as well as to help regulate excess salt and freshwater. It also supplies
oxygen rich water from the Gulf. In the absence of surface water circulation or tidal activity,
estuarine habitats, such as mangroves,can slowly die due to deleterious changes in the sediment
because in the absence of oxygenated water the sediments become anaerobic or anoxic, and
metabolic wastes and hydrogen sulfide accumulate in the anoxic sediment(CBRMP, 1998).
Tides in the Gulf of Mexico are mixed, with the norm being two high tides and two low tides
experienced per day and normal amplitude(range) of approximately 2 feet. The highest tides
(springs) are experienced twice per lunar month at full and new moons when the gravitational
pull on the Earth's surface waters is greatest. Neap tides also occur twice per lunar month when
the planetary(gravitational)influences of earth,moon and sun are perpendicular.
CLAM BAY TIDAL RANGES
2.50 C3 PRE-DREDGE RANGE
O POST-DREDGE RANGE
■10/99-01/2000 RANGE
O 03/00-05/00 RANGE
■06/00-07/00 RANGE
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002/01-05/01 RANGE
■07/01-08/01 RANGE
r, ■09/01-11/01 RANGE
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It can be seen that the health of the mangrove forests is directly related to the efficiency of the
tidal pass. Clam Pass and its associated waterway is a very dynamic creek whose location has
varied over time(Turrell 1995; Tackney 1996). Because of this,it is susceptible to outside
events and can periodically close, such as has happened at least six times in the last 25 years.
The following aerial photographs show how the Pass and its waterway have changed over the
past 60 years.
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Tidal creeks are passageways for fish and marine invertebrates between the open waters of the
Gulf and the protected embayments of Clam Bay. Manatees, dolphins, and turtles may also use
the Pass. Scouring action of the fast flowing tide generally prevents colonization by seagrasses
and other benthic plants, and the substrate is typically sand and shell with the finer sediments
carried in suspension and deposited just outside the mouth of the Pass(the ebb shoal delta)or to
the interior of the system on the incoming(flood) tide.
FLUCFCS Code 612—Mangrove Swamps (Forest)
Mangroves are salt tolerant trees that grow in tidal areas of the tropics and are legally protected
for their ecological value with such functions as:
• Providing habitat for marine,terrestrial, and avian wildlife.
• Protecting coastal areas from storm surges and coastal erosion.
• Improving water quality by acting as a natural filter for land based freshwater run-off.
• Forming the basis of a highly productive estuarine food chain which includes many
commercially valuable species.
• Enhancing the atmosphere by absorbing carbon dioxide and reducing greenhouse gasses.
Special attention has been given to the mangrove community in the past because of the die-off
which occurred between 1991 and 1997 (though stress in the community was documented as far
back as the late 1970's). The die-off affected black and red mangroves initially but eventually
ended up encompassing some white mangroves as well. More details on the recent history of the
mangrove management are provided in Appendix 3 included with this plan.
Red Mangroves
Red mangroves (Rhizophora mangle) are recognized by their tangle of reddish looking prop
roots, long cigar shaped seedlings (propagules) and their large,pointed evergreen leaves. Red
mangroves flower all year but reach maximum propagule production during the late spring and
early summer months. They are typically the most seaward of the three species with the prop
roots and vertical drop roots providing support. Small pores on the trunks called lenticels allow
oxygen exchange via air as the waterlogged soils become rapidly oxygen depleted. Salt is
excluded from the plants cells through a process called ultra-filtration roots. The characteristic
propagules germinate on the parent tree and drop and float for up to a year, finally becoming
heavier at one end so that when encountering a suitable substrate they are ready to root upright.
The mass of prop and drop roots forms extensive surface area under water for attachment of
sessile, filter feeding marine species(such as sponges,tunicates, and mollusks) as well as hiding
places for juvenile fish. Birds,butterflies,insects, and mammals find home and food within the
canopy.
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Black Mangroves
Black mangroves(Avicennia germinans) are typically found a little further inland. Key
identification features include the snorkel like pneumatophores which radiate upwards out of the
soil from the base of the trunk, a grey-black rough bark and slightly pointed, oval leaves which
are silvery with salt deposits on the undersides. The pneumatophores play an important role in
oxygen exchange and unlike the red mangroves,which keeps salt out of the body cells through
filtration in the roots,the black mangrove excretes salt out of the backside of the leaves. They
are also reliant on adequate tidal exchange but lack the supporting prop roots that typify the red
mangrove. Small white flowers and lima bean shaped propagules are typically apparent during
the late spring and early summer months. Black mangroves are cryptoviviparous as the embryo
develops within the fruit while on the parent plant. When these propagules fall from the parent
tree,they are able to float for a short period before rooting in the mucky soil.
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White Mangroves
White mangroves(Laguncularia racemosa) are the third mangrove species and are often found
further inland than the other two species, Although zonations described are typical they can
frequently vary. Since they often occur in drier areas,white mangroves do not exhibit the
adaptations to soft, anaerobic soil of the other species. The bark is characteristically grooved and
furrowed, and leaves are oval,mid-green and leathery with two small glands on the petiole at the
base of each leaf. White mangroves also flower in the spring and early summer, and the small
seedlings have the shortest floating dispersal stage of the three species. White mangroves are
semi-viviparous and germinate inside the fruit during the approximately five-day dispersal,but
not while attached to the parent plant.
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The mangrove communities are composed of both riverine(along the creeks) and basin forest
components. The species composition of mangroves within these two community components is
very distinctive. Riverine mangrove areas are almost exclusively composed of red mangroves
within the Clam Bay NRPA while all three species, along with buttonwood(Conocarpus
erectus), are found in the forest component.
Riverine(Creeks)Mangroves
On the waterward edges of small islands and the tidal creeks,passes and estuarine waterways
that make up the Clam Bay system, a fringe of red mangroves will be found growing up to 25
feet in height. This zone can be just one or two trees in depth or extend landward for some
distance, depending on topography. The habitat provided by the prop roots of these red
mangroves is of great importance to many fish and other aquatic organisms.
Forests
The majority of the Clam Bay mangrove habitat is low-lying basin forest where the dominant
mangrove species varies between red,white, and black through the forest habitat. This forest
community was the habitat affected by the mangrove die-off. The hand dug flushing channels
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were constructed throughout this community to increase the flushing capacity through tidal
inundation.
Associated plants within the mangrove habitat include: buttonwood(Conocarpus erectus), the
succulent ground covers, saltwort(Batis maritima) and glasswort(Salicornia cervicornis),
(especially where a fallen tree provides a break in the canopy and light penetration to the forest
floor) and, further inland and closer to freshwater sources,the leather fern(Acrostrichum
1 danaefolia).
FLUCFCS Code 642—Salt Marsh
i
At the interface between forested mangrove areas and the water management berm are
depressional areas that have become colonized by aquatic freshwater plants, such as cattails
(Typha latifolia), Carolina willow(Salix caroliniana),bulrush(Scirpus californicus),needlerush
(Juncus romerianus), and leather fern(Acrostichum danaeifolium). For a more complete list of
common plant species found in this habitat see page 53. Wildlife,such as otters(Lutra
canadiensis), alligators (Alligator mississippiensis),various turtles, and wading birds can be
commonly observed. These areas require regular maintenance to prevent the spread of nuisance
and exotic plant species and ensure optimal functioning and interface between the natural
mangrove forest and the water management system.
FLUCFCS Code 651—Tidal Flats
Tidal flats are flat bottomed, sub-or intertidal habitats that lack an oyster or seagrass community
and are located inside the outer coastal margin. The two most significant environmental
characteristics that control a flat's infauna(benthic organisms that live within the substrate) and
epifauna(benthic organisms that live on the surface of the substrate)are: the height of the
substrate relative to mean sea level and the sedimentary consistency of the substrate. The
position relative to mean sea level dictates whether the habitat is emergent(in air)for part of a
tidal cycle or how deep below the water it is. This latter characteristic controls other physical
water quality measures, such as dissolved oxygen, the frequency and duration of hypoxic events,
and light penetration. Firmness of the substrate affects the capacity to support an epifauna by
both supporting the organism on the substrate and permitting the burrowing of the infauna.
The sand and mudflats of Clam Bay are rich feeding grounds for many species of fish and
wading birds. These organically rich sediments support a variety of mollusks, worms, and
invertebrates that scavenge detritus or,in the case of many bivalve mollusks, extend siphons at
high tide and filter vast quantities of water. Birds, such as a variety of herons, ibis, egrets, and
spoonbills pick through the sediment for the invertebrate food sources.
The dredging of the Pass associated with the 1998 Restoration and Management Plan resulted in
an increase of exposed tidal flats within the southern portion of the system. Increased tidal range
resulting from the dredging allowed more area to be periodically exposed during the tidal cycle.
Some of the area that had supported seagrasses prior to the dredging work were converted into
the tidal flats by the increased range and reduced phase lag. Management concerns related to the
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tidal flats include the templates established for the dredging, the resultant currents that could be
expected as a result of dredging, and the frequency of disturbance.
FLUCFCS Code 911 —Seagrass Beds
Seagrasses are flowering marine plants of shallow, tropical regions. With a creeping growth
form connected by horizontal rhizomes they serve to trap and anchor sediment. Both the grass
blades themselves and the surface area they represent provide food and attachment for marine
species. Seagrass beds are renowned for their value as nursery habitats and are legally protected.
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Paddle grass (Halophila decepiens) in the center of Outer Clam Bay
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ITurtle grass (Thalassia testundinum)just south of County boardwalk in Outer Clam Bay
Seagrasses rely on good light penetration to enable photosynthesis and are sensitive to reduced
tidal water quality. Growing in shallow regions, they are also vulnerable to physical damage by
3 boats. A variety of marine algae can be associated with grass species, differing in the lack of a
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true rooting and vascular system. Several species of both brown and green alga have been
observed.
Other Benthic Habitats
Oyster Bars
Oysters (Croassostrea americana) are filter-feeding bivalves, which were once common within
the tidal creeks of Clam Bay(Humm and Rehm 1972). Oysters play a significant role in shaping
the environment in which they live by forming a hard structure upon which an intricate
biological community is built. Similar to coral reefs, oyster reefs are `biogenic' (formed by the
accumulation of colonial animals) and provide structure and surface area for numerous other
temporary and permanent species.
Providing complex habitat structure is the most fundamental of ecosystem services that oysters
provide. The structure provides a place for algae and non-mobile invertebrates to attach, as well
as a place for mobile invertebrates and fishes to be protected from predators.Although the
relationships between sportfish and oyster habitats are not as well studied as in other estuarine
habitats, such as seagrass beds,they are considered essential fish habitat.
The numerous ecosystem services provided by oysters can be summarized into three general
categories: habitat provision,water quality improvement, and shoreline stabilization. Oyster
reefs provide habitat to a diverse array of flora and fauna. The role of oyster habitat to the
estuarine food chain is highly significant, as discussed in the previous paragraph. Through their
feeding process oysters filter large quantities of water which transfers energy and material from
the water column to the benthic community, subsequently reducing turbidity and water column
nutrients. Through bio-deposition,nutrients are made available to the flora and fauna which
comprise the complex oyster bar food web. Additionally, oyster reefs stabilize sediments,
shorelines and adjacent habitats by buffering wave energy, further aiding water quality.
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Oysters(Croassostrea americana)along the mangroves near the canoe ramp in Outer Clam Bay
A 2011 benthic habitat assessment conducted by the Conservancy of Southwest Florida found
living oyster clusters in the upper reaches of Upper Clam Bay(a single cluster), in the tributary
between Outer and Inner Clam Bays(a single cluster), and throughout the shoreline of Outer
Clam Bay.
Other bivalve mollusks
i
In addition to oysters, the 2011 benthic habitat assessment conducted by the Conservancy of
Southwest Florida also found two other bivalves within the Clam Bay system. The pointed
venus clam(Anomalocardia auberiana) and the stout razor clam(Tagelus plebeius)were both
observed. Turrell, Hall &Associates, Inc.benthic surveys found several beds of southern hard
clams (Mercenaria campechiensis) also present in the system.
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Southern hard clam (Mercenaria campechiensis)from waterway south of Clam Pass
These mollusks are generally found within the shoal and tidal flat areas of the system and could
be susceptible to impact during dredging or other disturbance operations. Management concerns
would be protection from recreational users, water quality, flushing and dredging.
Tubiculous Polychaetes
Tubiculous polychaetes (tube worms)are typically the most abundant biological assemblage in
Clam Bay and are primarily associated with muddy and sandy substrates. Polychaetes, including
worm tubes and mud tubes, shell-encrusted polychaete tubes (Polychaeta) and trumpet worm
(Pectinaria gouldi)tubes, are a vital component of the estuarine food web,providing key
linkages between primary producers and higher trophic levels. Polychaetes create habitat and
food for many organisms, such as mollusks, fish and even sea turtles. These worms are usually
filter or deposit feeders that keep the substrate aerated and free of waste accumulation.
Polychaetes tend to dominate Inner and Outer Clam Bays,with lower occurrences in Upper
Clam Bay, the Lower Tributary, and,to a lesser extent,the Upper Tributary.
Hardbottom Communities
Another important marine habitat marginally associated with the estuarine system is the hard
bottom reef community found just seaward of Clam Pass. In about 10-15 feet of water a variety
of sponges, stony corals, gorgonians, fish and associated invertebrates can be found within a
system of rocks and ledges. Outcroppings of similar habitat type occur along the length of
Collier County and are a little known resource of regional significance.
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Hardbottom outcrop off of Clam Pass
Collier County has mapped this resource through side scan sonar surveys in 2005 and 2009 as
part of its beach renourishment project. The information received from the County shows that
the landward edge of this habitat is located approximately 250 to 300 feet offshore from the Pass.
Invasive,Non-native and Problem Species
In an ecological context, an invasive species is one that is aggressive in growth and expansion of
range and tends to dominate other appropriate native species. Its establishment and dominance
can cause widespread harm to an ecological system by altering the species composition,
susceptibility to fire and hydrology of an area. Non-indigenous species (i.e.,non-native or exotic
species)are those that have been introduced purposefully or accidentally to an area outside their
normal range. The characteristics of some of these species (high rate of growth/reproduction,no
natural predators, easily dispersed, able to out-compete native species)make them invasive.
Some indigenous species (a species whose natural range included Florida at the time of European
contact circa 1500 AD or a species that has naturally expanded or changed its range to include
Florida)may also become invasive. Invasions by native and non-native species often follow an
1 alteration to ecosystem function, disruption of the food web, large-scale fragmentation of an
I ecosystem and/or disturbance(e.g., clearing, fire, drought, etc.)of an area. While some native
1 species may become invasive,the establishment and dominance of non-native species is of
particular concern. The exotic species documented within the NRPA and those that have a
I potential to occur within the NRPA are discussed in the following section.
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Invasive and Problem Plant Species
The Florida Exotic Pest Plant Council(FLEPPC)maintains a list of exotic plants that have been
documented to (1)have adverse effects on Florida's biodiversity and plant communities, (2)
cause habitat loss due to infestations, and(3) impact endangered species via habitat loss and
alteration. To date, 9 non-indigenous plant species have been detected within the Clam Bay
NRPA which are listed by FLEPPC as Category I exotics. FLEPPC defines Category I plants as
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those that alter native plant communities by displacing native species, change community
structures or ecological functions, or hybridize with natives. Category II plants have increased in
abundance or frequency but have not yet altered Florida plant communities to the extent shown
by Category I species. These definitions do not rely on the economic severity or geographic
range of the problem,but rather on the documented ecological damage caused by these plants
(FLEPPC 2013).
FLEPPC Category I plants observed within the Clam Bay NRPA boundary:
- Brazilian Pepper(Schinus terebinthifolius)
- Melaleuca(Melaleuca quinquenervia)
- Australian Pine (Casuarina equisetifolia)
- Beach Naupaka(Scaevola taccada)
- Earleaf Acacia(Acacia auriculiformis)
- Shoebutton Ardisia(Ardisia elliptica)
- Air Potato(Dioscorea bulbifera)
- Lantana(Lantana camara)
- Old World Climbing Fern(Lygodium microphyllum)
FLEPPC Category II plants observed within the Clam Bay NRPA boundary:
- Coconut Palm(Cocos nucifera)
- Wedelia(Sphagneticola trilobata)
- Oyster Plant(Tradescantia spathacea)
- Mahoe(Talipariti tiliaceum)
Methodology outlining the management activities that will be used to treat exotics is found in
Chapter 5 of this Management Plan.
Listed Species
Smalltooth Sawfish(Pristis pectinata)
A juvenile smalltooth sawfish was observed in 2008 in the connector creek between Inner and
Outer Clam Bays. Smalltooth sawfish are found in the tropical and subtropical Atlantic Ocean.
In the western Atlantic they have historically ranged from New York to Brazil, including the
Gulf of Mexico and Caribbean Sea. Habitat destruction and overfishing have succeeded in
eradicating the smalltooth sawfish from the majority of its former range. Consequently,it
survives in small pockets throughout its current range. The last remaining population in U.S.
waters is off south Florida, a small remnant of a population that once ranged from New York to
Texas.
This sawfish primarily occurs in estuarine and coastal habitats such as bays,lagoons, and rivers.
It does at times occur in deeper waters,however, and may make crossings to offshore islands. It
can tolerate freshwater. This fish is easily recognized by its flattened body and wing-like
pectoral fins. The mouth is located ventrally, and the eyes are positioned dorsally. The"saw"is
approximately 25%of the body's total length. It is widest at the base,with teeth more broad than
long, and spaced apart. The tips of the teeth are sharp,becoming blunt over time. Dorsally, it is
brownish or bluish gray body with a white underside. The maximum length recorded is 24.7 feet
(7.6 m);however, a length of 18 feet(5.5 m)is considered average. The average lifespan for the
smalltooth sawfish is unknown.
On April 1,2003 the U.S.National Marine Fisheries Service placed the smalltooth sawfish on
the Endangered Species List,making it the first marine fish species to receive protection under
the Endangered Species Act. Florida has also designated critical habitat areas to further protect
its habitat.
Mangrove Rivulus (Rivulus marmoratus)
This small fish has not been identified within the Clam Bay system in previous surveys or field
work but the mangrove habitat is appropriate, and they could be present in the upper reaches of
the mangrove forest. The mangrove rivulus is primarily a saltwater or brackish water species,
with limited occurrence in freshwater. Within the Everglades and along Florida's west coast,
this fish occurs in stagnant, seasonal ponds, and sloughs as well as in mosquito ditches within
mangrove habitats. The mangrove rivulus is able to survive in moist detritus without water for
up to 60 days during periods of drought, anaerobic, or high sulfide conditions.
This fish can reach a maximum size of 2 inches(5 cm) in length,however it is more commonly
observed at lengths between 0.4-1.5 inches(1.0-3.8 cm). The head and body are maroon to dark
brown or tan,with small dark spots and speckling on the body,particularly the sides. The dorsal
surface is always darker than the creamy ventral surface. The color of the body is reflective of
the habitat,with light coloration in areas of light colored sediments and darker coloration in
environments with dark leaf litter substrates. A large dark spot surrounded by a band of yellow
is located at the upper base of the caudal fin in hermaphroditic individuals. Males lack this dark
spot and have a red-orange cast to their flanks and fms.
The mangrove rivulus was once listed as a threatened species in the Gulf of Mexico. However,
recently additional surveys have revealed the existence of numerous populations. In Florida it
has been downlisted to a species of special concern. In 1999,it was submitted by the National
Marine Fisheries Service as a candidate for protection under the Endangered Species Act. As of
yet, it has not been officially listed as endangered or threatened.
The main threat to the survival of the mangrove rivulus is habitat degradation and destruction as
well as exposure to pollutants. Disturbances that alter salinity and temperature as well as
vegetation cover may also reduce naturally occurring populations.
Loggerhead Sea Turtle(Caretta caretta)
Loggerhead sea turtles have been documented nesting on beaches within the Clam Bay NRPA.
Loggerheads are circumglobal, occurring throughout the temperate and tropical regions of the
Atlantic,Pacific and Indian Oceans. They are the most abundant species of sea turtle found in
the U.S.coastal waters. In the Atlantic,the loggerhead turtles range extends from Newfoundland
to as far south as Argentina.
During the summer,nesting occurs primarily in the subtropics. Although the major nesting
concentrations in the U.S. are found from North Carolina through southwest Florida,minimal
nesting occurs outside of this range westward to Texas and northward to Virginia. Adult
loggerheads are known to make extensive migrations between foraging areas and nesting
beaches. During non-nesting years, adult females from U.S.beaches are distributed in waters off
the eastern U.S. and through the Gulf of Mexico,Bahamas,Greater Antilles, and Yucatan.
Loggerheads were named for their relatively large heads,which support powerful jaws and
enable them to feed on hard-shelled prey, such as whelks and conch.The top shell(carapace)is
slightly heart-shaped and reddish-brown in adults and sub-adults,while the bottom shell
(plastron)is generally a pale yellowish color. The neck and flippers are usually dull brown to
reddish brown on top and medium to pale yellow on the sides and bottom.
In the southeastern U.S.,mating occurs in late March to early June and females lay eggs between
late April and early September. Females lay three to five nests, and sometimes more, during a
single nesting season. The eggs incubate approximately two months before hatching sometime
between late June and mid-November.
Loggerheads occupy three different ecosystems during their lives:beaches(terrestrial zone),
water(oceanic zone), and nearshore coastal areas ("neritic" zone). Because of this,NOAA
Fisheries and the U.S. Fish and Wildlife Service(USFWS)have joint jurisdiction for marine
turtles,with NOAA having the lead in the marine environment and USFWS having the lead on
the nesting beaches.
The loggerhead turtle was first listed under the Endangered Species Act as threatened throughout
its range on July 28, 1978. In September 2011,National Marine Fisheries Service(NMFS) and
USFWS listed 9 Distinct Population Segments of loggerhead sea turtles under the Endangered
Species Act(ESA). The population in the Northeast Atlantic Ocean Segment is listed as
endangered. The agencies are currently proposing Critical Habitat designations on several areas
which contain a combination of nearshore reproductive habitat,winter area,breeding areas, and
migratory corridors. The Clam Bay NRPA is contained within the LOGG-N-27 segment of this
proposed critical habitat area.
Gopher Tortoise (Gopherus polyphemus)
Gopher tortoises and their burrows are found along the coastal strand portions of the Clam Bay
NRPA. The range of the tortoise includes southern portions of Alabama, South Carolina,
Louisiana,Mississippi, and Georgia as well as most of Florida.
Gopher tortoises are one of the few species of tortoise that dig burrows. These burrows can be
up to ten feet deep and 40 feet long, and are as wide as the length of the tortoise that made it. In
addition to providing the tortoise a home,it has been documented that as many as 350 other
species also use the burrows including the indigo snake,Florida mouse, gopher frog, and
burrowing owl.
Gopher tortoises can live 40 to 60 years in the wild and average 9 to 11 inches in length. These
tortoises are superb earth-movers, living in long burrows from 5 to 45 feet long and up to 10 feet
deep that offer refuge from cold,heat, drought, forest fires, and predators. The burrows maintain
a fairly constant temperature and humidity throughout the year and protect the gopher tortoise
Amor
and other species from temperature extremes,drying out, and predators. The mating season
generally runs from April through June and gestation for the eggs is between 80 and 100 days.
The shell or"carapace" of the gopher tortoise is mostly brownish gray and the underside of the
shell, or"plastron," is yellowish tan. Their front legs are shovel-like which helps them when
digging their burrows.
The gopher tortoise has been regulated in Florida since 1972 and has been fully protected since
1988. Despite the afforded protection, gopher tortoise populations throughout the state have
declined. As a response to the continuing decline of the species, a new management plan was
drafted and approved in September 2007 as a precursor to reclassifying the gopher tortoise from
a"species of special concern"to a "threatened species." The threatened status was approved and
went into effect on November 8,2007.
Piping Plover(Charadrius melodus)
Piping plovers have been rarely sighted foraging or resting along the shoreline within the Clam
Bay NRPA boundaries. No nesting activities have been documented within the NRPA.
Piping plovers are small shorebirds approximately seven inches long with about a 19 inch
wingspan. They have sandy/grey colored plumage on their backs and crown and white
underparts. Breeding birds develop a single black breast band, a black bar across the forehead,
bright orange legs, and bill with a black tip on the bill. During the winter,the birds lose the
black bands,the legs fade to pale yellow, and the bill becomes mostly black.
Piping plovers breed in three geographic regions of North America: the Atlantic Coast(which is
where the Clam Bay NRPA is located),the Northern Great Plains, and the Great Lakes. Nesting
in the Atlantic Coast region occurs on coastal beaches, sand flats, and bars associated with
barrier islands, gently sloped and sparsely vegetated dunes, and washover areas cut into or
between dunes. Plovers from all three breeding populations winter along South Atlantic,Gulf
Coast, and Caribbean beaches and barrier islands,primarily on intertidal beaches with sand
and/or mud flats with no or very sparse vegetation.
Piping plover populations were federally listed as threatened and endangered in 1986. The
Northern Great Plains and Atlantic Coast populations are threatened, and the Great Lakes
population is endangered. Piping plovers are considered threatened throughout their wintering
range. The highest concentration of birds reported in winter censuses are found in Texas,
Louisiana, and Florida. In recent decades,piping plover populations have drastically declined as
breeding habitat has been replaced with shoreline development and recreation. (USFWS).
West Indian Manatee(Trichechus manatus)
Manatees have been sighted on numerous occasions within the Clam Bay NRPA boundaries.
Manatees can be found in shallow, slow moving rivers, estuaries,saltwater bays, canals, and
coastal areas particularly where seagrass beds or freshwater vegetation flourish. Manatees are a
migratory species. Within the U.S.,they are concentrated in Florida in the winter. In summer
months,they can be found as far west as Texas and as far north as Massachusetts,but summer
sightings in Alabama, Georgia and South Carolina are more common.
Manatees are large, gray aquatic mammals with bodies that taper to a flat,paddle-shaped tail.
They have two forelimbs, called flippers, with three to four nails on each flipper. The average
adult manatee is about 10 feet long and weighs between 800 and 1,200 pounds. They eat a large
variety of submerged, emergent, and floating plants and can consume 10-15%of their body
weight in vegetation daily. Because they are mammals,they must surface to breathe air. They
rest just below the surface of the water, coming up to breathe on an average of every three to five
minutes. It is believed that one calf is born every two to five years, and twins are rare. The
gestation period is about a year. Mothers nurse their young for one to two years, during which
time a calf remains dependent on its mother.
Protections for Florida manatees were first enacted in 1893. Today,they are protected by the
Florida Manatee Sanctuary Act and are federally protected by both the Marine Mammal
Protection Act and the ESA.
Other Species
Plant Species—List based on FLUCFCS Mapping
Table 5:Representative Plant Species found within the NRPA Boundary
FLUCFCS Code 181 —Swimming Beach
COMMON NAME SCIENTIFIC NAME
Seagrape Coccoloba uvifera
Sea Oats Uniola paniculata
Railroad vine Ipomoea pes-caprae
FLUCFCS Code 322 —Coastal Scrub
COMMON NAME SCIENTIFIC NAME
Seagrape Coccoloba uvifera
Cabbage Palm Sabal Palmetto
Buttonwood Conocarpus erectus
Spanish Bayonet Yucca aloifolia
Saltbush Baccharis halimifolia
Beach Naupaka Scaevola taccada
FLUCFCS Code 428—Cabbage Palm Hammock
COMMON NAME SCIENTIFIC NAME
Cabbage Palm Sabal palmetto
Seagrape Coccoloba uvifera
Strangler Fig Ficus aurea
Saffron Plum Sideroxylon celastrinum
Coinvine Dalbergia ecastaphyllum
Brazilian Pepper Schinus terebinthifolia
Beach Naupaka Scaevola taccada
FLUCFCS Code 612—Mangrove Swamps (Forest)
COMMON NAME SCIENTIFIC NAME
Red Mangrove Rhizophora mangle
White Mangrove Laguncularia racemosa
Black Mangrove Avicennia germinans
Buttonwood Conocarpus erectus
Leather Fern Acrostichum danaeifolium
Saltwort Batis maritima
FLUCFCS Code 642—Salt Marsh
COMMON NAME SCIENTIFIC NAME
Lance-leaf Arrowhead Sagittaria lancifolia
Needlerush Juncus roemerianus
Bulrush Scirpus californicus
Carolina Willow Salix caroliniana
Peruvian Primrosewillow Ludwigia peruviana
Animal Species
The following list of species has been observed within the Clam Bay NRPA and the adjacent
Pelican Bay development areas. These lists are not all inclusive but represent a wide array of the
species found within and adjacent to the Clam Bay NRPA habitats.
Aquatic Invertebrates From Conservancy Report
Table 6:Aquatic Invertebrate species found within the NRPA boundary
COMMON NAME SCIENTIFIC NAME
American Oyster Crassotrea virginica
Brittlestar Ophiophragmus filograneus
Florida Crown Conch Melongena corona
Grass Cerith Bittiolum varium
Heart Urchin Moira atropos
Painted Venus Clam Anomalocardia auberiana
Shell-encrusted tubes
Stout Razor Clam Tagelus plebeius
Trumpet worm tubes Pectinaria gouldi
Unidentified mud tubes
Unidentified worm tubes
Fish
Table 7: Fish species found within the NRPA boundary
COMMON NAME SCIENTIFIC NAME
Atlantic needlefish Strongylura marina
Barracuda Sphyraena barracuda
Bay anchovy Anchoa mitchilli
Blacktip Shark Carcharhinus limbatus
Blue crab Callinectis sapidus
Cowfish Acanthostracion quadricomis
Flounder Paratichthys alb!gutta
Gray snapper Lutjanus griseus
Great barracuda Sphyraena barracuda
Gulf killifish Fundulus grandis
Inshore Iizardfish Synodus foetens
Killifish spp. Fundulus spp.
Leatherjacket Oligoplites saurus
Longnose killifish Fundulus simitis
Mangrove snapper Lutjanus griseus
Mullet Mugil cephalus
Mutton snapper Lutjanus anatis
Needlefish Strongylura marina
Permit Trachinotus falcatus
Pigfish Orthopristus chrysoptera
Pinfish Lagodon rhomboides
Pipefish Syngnathus spp.
Puffer Sphoeroides parvus
Sailfin molly Poecilia latipinna
Sand perch Diplectrum bivittatum
Scaled sardine Harengula pensacolae
Sea robin Prionotus scitulus
Sheepshead Archosargus probatocephal
Sheepshead minnow Cyprinodon variegatus
Silver jenny Eucinostomus gula
Smalltooth Sawfish* Pristis pectinata
Snook Centropomus undecimalis
Spot Leiostomus xanthurz-us
Spotfin mojara Eucinostomus argenteus
Spotted seatrout Cynoscion nebulosus
Tidewater silverside Menidia peninsulae
Triggerfish Batistes capriscus
White grunt Haeinulon plumierii
Whiting Menticirrhus tittoratis
Reptiles and Amphibians
Table 8:Reptile and Amphibian species found within the NRPA Boundary
COMMON NAME SCWNTIFIC NAME
SNAKES
Banded water snake Nerodia faciata faciata
Black racer Coluber constrictor
Common garter snake Thamnophis sirtalis
Eastern coachwhip Masticophis flagellum
Mangrove salt marsh water snake Nerodia clarkii
Mud snake Farancia abacura
Red rat snake* Elaphe guttata guttata
Ring-necked snake Diadophis punctatus
Yellow rat snake Elaphe obsoleta
LIZARDS AND CROCODILIANS
American alligator* Alligator mississippiensis
Brown anole Anolis sagrei
Brown basilisk lizard Basiliscus vittatus
Cuban knight anole Anolis equestris
Eastern glass lizard Ophisaurus ventralis
Green anole Anolis carolinensis
Southeastern five-lined skink Eumeces inexpectatus •
FROGS AND TOADS
Cuban treefrog Osteopilus septentrionalis
Eastern narrow-mouthed toad Gastrophryne carolinensis
Eastern spadefoot toad Scaphiopus holbrookii
Giant marine toad Rhinella marina (fka Bufo marinus)
Green treefrog Hyla cinerea
Oak toad Anaxyrus quercicus
Southern leopard frog Lithobates sphenocephalus
Southern toad Bufo terrestris
Squirrel treefrog Hyla squirella
TURTLES AND TORTOISES
Chicken turtle Deirochelys reticularia
Florida box turtle Terrapene carolina bauri
Florida redbelly cooter Pseudemys nelsoni
Florida snapping turtle Chelydra serpentina osceola
Florida softshell turtle Apalone ferox
Gopher tortoise* Gopherus polyphemus
Green sea turtle* Chelonia mydas
Loggerhead sea turtle* Caretta caretta
Penninsula cooter Pseudemys peninsularis
Pond(yellowbelly) slider Trachemys scripta scripta
Striped mud turtle* Kinosternon baurii
Birds
Table 9:Bird species found within the NRPA Boundary
COMMON NAME SCIENTIFIC NAME
American avocet Recurvirostra americana
American coot Fulica americana
American kestrel Falco sparverius
American oystercatcher* Haematopus palliatus
American Robin Turdus migratorius
Anhinga Anhinga anhinga
Bald eagle Haliaeetus leucocephalus
Barred owl Strix varia
Belted kingfisher Megaceryle alcyon
Black skimmer* Rynchops niger
Black vulture Rynchops niger
Black-and-white warbler Mniotilta varia
Black-bellied plover Pluvialis squatarola
Black-crowned night heron Nycticorax nycticorax
Black-necked stilt Himantopus mexicanus
Blue jay Cyanocitta cristata
Blue-gray gnatcatcher Polioptila caerulea
Boat-tailed grackle Quiscalus major
Brown pelican* Pelecanus occidentalis
Brown thrasher Toxostoma ra firm
Budgerigar Melopsittacus undulatus
Caspian tern Hydroprogne caspia
Cattle egret Bubulcus ibis
Chuck-will's-widow Caprimulgus carolinensis
Common grackle Quiscalus quiscula
Common ground-dove Columbina passerina
Common moorhen Gallinula chloropus
Common nighthawk Chordeiles minor
Common snipe Gallinago gallinago
Common tern Sterna hirundo
Common yellowthroat Geothlypis trichas
Double-crested cormorant Phalacrocorax auritus
Dowitcher long-billed Limnodromus scolopaceus
Dowitcher short-billed Limnodromus griseus
Downy woodpecker Picoides pubescens
Dunlin Calidris alpina
Eastern screech owl Megascops asio
Eurasian collared dove Streptopelia decaocto
European starling Sturnus vulgaris
Fish crow Corvus ossifragus
Forster's tern Sterna forsteri
Glossy ibis Plegadis falcinellus
Gray catbird Dumetella carolinensis
Great blue heron Ardea herodias
Great crested flycatcher Myiarchus crinitus
Great egret Ardea alba
Great horned owl Bubo virginianus
Greater yellowlegs Tringa melanoleuca
Green heron Butorides virescens
Green-winged teal Anas crecca
Herring gull Larus argentatus
Hooded merganser Lophodytes cucullatus
House sparrow Passer domesticus
Killdeer Charadrius vociferus
Laughing gull Leucophaeus atricilla
Least sandpiper Calidris minutilla
Limpkin* Aramus guarauna
Little blue heron* Egretta caerulea
Loggerhead shrike Lanius ludovicianus
Magnificent frigate bird Fregata magnificens
Mangrove cuckoo Coccyzus minor
Merlin Falco columbarius
Mocking bird Mimus polyglottos
Mottled duck Anas fulvigula
Mourning dove Zenaida macroura
Muscovy duck Cairina moschata
Northern cardinal Cardinalis cardinalis
Northern gannet Morus bassanus
Northern parula Parula americana
Northern waterthrush Seiurus noveboracensis
Osprey* Pandion haliaetus
Painted bunting Passerina ciris
Palm warbler Dendroica palmarum
Peregrine falcon Falco peregrinus
Pied-billed grebe Podilymbus podiceps
Pilleated woodpecker Dryocopus pileatus
Piping plover* Charadrius melodus
Prairie warbler Dendroica discolor
Purple gallinule Porphyrula martinica
Red knot Calidris canutus
Red-bellied woodpecker Melanerpes carolinus
Red-breasted merganser Mergus serrator
Reddish egret* Egretta rufescens
Red-shouldered hawk Buteo lineatus
Red-tailed hawk Buteo jamaicensis
Red-winged blackbird Agelaius phoeniceus
Ring-billed gull Larus delawarensis
Roseate spoonbill* Platalea ajaja
Royal tern Sterna maxima
Ruby-throated hummingbird Archilochus colubris
Ruddy turnstone Arenaria interpres
Sanderling Calidris alba
Sandwich tern Sterna sandvicensis
Semipalmated plover Charadrius semipalmatus
Snowy egret* Egretta thula
Spotted sandpiper Actitis macularia
Swallow-tailed kite Elanoides forficatus
Tri-colored heron* Egretta tricolor
Turkey vulture Cathartes aura
Western sandpiper Calidris mauri
White ibis* Eudocimus albus
White pelican Pelecanus erythrorhynchos
Willet Catoptrophorus semipalmatus
Wood stork* Scolopax minor
Yellow-bellied sapsucker Sphyrapicus varius
Yellow-crowned night heron Nyctanassa violacea
Yellow-rumped warbler Dendroica coronata
Yellow-throated warbler Dendroica dominica
Mammals
Table 10:Mammal species found within the NRPA Boundary
COMMON NAME SCIENTIFIC NAME
Big brown bat Eptesicus fiuscus
Bobcat Lynx rufus
Bottle-nosed dolphin Turciops truncatus
Brazilian free-tailed bat Tadarida braziliensis
Coyote Canis latrans
Eastern gray squirrel Sciurus carolinensis
Eastern mole Scalopus aquaticus
Feral domestic cat Felis catus
Florida Black bear Ursus americanus floridanus
Gray fox Urocyon cinereoargenteus
House mouse Mus musculus
Marsh rabbit Sylvilagus palustris
Nine-banded armadillo Dasypus novemcinctus
Raccoon Procyon lotor
River otter Lutra canadensis
Roof rat Rattus rattus
Virginia opossum Didelphis virginia
West Indian manatee Trichechus manatus
Indicates Endangerd Species,Threatened Species, or Species of Special Concern
CLAM BAY NRPA MANAGEMENT PLAN(DRAFT)
Pelican Bay Services Division
May 30, 2014
Ver. 6.2
APPENDIX 5 - CLAM PASS
MAINTENANCE DREDGING
DESIGN CRITERA
Appendix 5 - Clam Pass Maintenance Dredging Design Critera
Bay Tide Range
The existing hydraulic monitoring program provides water level measurements at several
stations within the bay system. The hydraulic monitoring data provides a record of the tidal range
in the bay which is an indicator to the tidal prism or volume of water flowing through the inlet at
each tidal cycle. In this analysis a review of ratios of the bay tidal range to that of the gulf tide is
used as the monitoring indictor to the flow through the inlet. Figure 2 shows a definition sketch
illustrating the tidal ranges for the gulf and bay. The bay tidal range is typically smaller than that
of the gulf tide due to flow resistance through the inlet channel and shoal features. The figure
also shows the locations of two of the bay tidal gages that are used in this analysis to represent
the bay tide range.
Figure 3 shows a plot of the annual ratios of bay to gulf tide from 1998 to date. However, data
collected in 2006 and 2007 were insufficient to provide an annual representation of the tidal
range ratio. The figure indicates that when the inlet was hydraulically stable the ratio between the
bay and gulf tide was between 0.6 and 0.7 over 90% of the time. The data also show that this
ratio was below 0.5 prior to 1999 dredging when the inlet was unstable and in 2012 prior to the
inlet closure. Dredging occurred in 2002 and 2007 while the tide range ratio was within the
stable range. These dredging events were carried out based on physical monitoring data. In both
dredge events, approximately one-third of the 1999 dredge quantity had accumulated within the
dredge template at the time of dredging. In both dredge events the dredged material was placed
south of the inlet.
Physical Monitoring Data Analysis
In addition to the hydraulic monitoring program, analysis of the physical monitoring data is used
to characterize the flow areas and shoaling within the channel and flood shoal areas. The
physical monitoring data includes bathymetric surveys of the inlet channel, flood shoal and ebb
shoal features. The data analysis includes evaluation of the flow cross-section areas in three main
sections of the dredging template, Sections A, B and C. Figure 4 shows the dredge template and
the three monitoring segments. Section A represents the inlet channel, Section B represents the
seaward part of the flood shoal and Section C represents the bay side part of the flood shoal. The
analysis included evaluation of the cross section of flow below mean high water and volume of
sand within each segment. The cross section of flow was computed at each survey station spaced
approximately 50 feet apart. The average and minimum cross section areas were used as
indicators of the physical condition of the flow area through each of the three segments. The
cross section areas were compared to the design cross section area of 2013 dredging and the inlet
conditions in 2004 and 2008. The 2008 and 2004 inlet conditions were used as a background
benchmark for inlet conditions near equilibrium as the 2004 and 2008 survey were completed 2
years and 16 months following the 2002 and 2007 dredging event respectively. These conditions
represent the inlet at stable conditions after the post dredging adjustment phase.
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Section A Inlet Channel
The indicators used in this analysis were average cross section area, minimum cross section area
and total volume of sand within Section A.
Figure 5 shows the change of average flow cross- section area below mean high water for
Section A. The figure covers the time period from January 2013 (pre-dredging conditions) to
April 2014 (12 months post-dredging). The figure shows the change in cross-section area from
pre-dredging conditions when the inlet was closed and its evolution immediately following
dredging to 4 months, 7 months, and 12 months post dredging. The figure also shows the
benchmark reference areas for the 2004 and 2008 average cross sections and the 2013 design
cross section area. The data indicate that following the inlet opening in 2013 the average cross
section shoaled below the design area while the inlet morphologic features were forming. After
the initial adjustments the cross section area increased to above the design area and 2008
conditions,but remained below the 2004 conditions.
Figure 6 shows the change of the minimum flow cross section area below mean high water for
Section A. The figure also shows the change in minimum cross section area from pre-dredging to
12 months post dredging with comparison to the 2004 and 2008 minimum cross sections and the
2013 design cross section area. The data indicate that following the inlet opening the minimum
cross section shoaled then steadily increased. The minimum cross section area remained smaller
than the design cross section area,but approaches the design cross section area after 12 months.
Figure 7 shows the change in total volume of sand accumulated in the dredge template since
inlet opening. The figure shows that the Section A dredge template has accumulated sand within
the dredge cut. It should be noted that the channel migrates and meanders within in the vicinity
of the dredge cut. Thus, this indicator should not be used as a measure of critical conditions of
the channel.
Figure 8 shows a table of the design criteria parameters for Section A with comparisons to post
dredging measurements. Recommended target values for each parameter are shown in red.
Section B Flood Shoal
The cross section area of flow through the flood shoal in Section B is an important indicator of
the flow exchange between the bay and inlet and the flow efficiency to maintain the tidal range
within the bay.
Figure 9 shows the change of average flow cross section area below mean high water for Section
B since inlet reopening. The figure covers the time period from January 2013 (pre-dredging
conditions when the inlet was closed) to 12 months post dredging in April 2014. The figure
shows how the average cross section evolved immediately following dredging to 4 months,
7 months and 12 months post dredging. The figure also shows the benchmark reference cross
section areas for the 2004 and 2008 conditions and the average design template dredged in 2013.
The data indicate that following the inlet opening the average cross section shoaled below the
design area while the inlet morphologic features were forming. This process has continued
throughout the 12 months post dredging. The cross section area remained larger than 2004 and
2008 conditions during the first 6 months post dredging then shoaled significantly in the
following 6 months. The 12 months post dredging data indicate that the average cross section
area within Section B became smaller than both historical benchmark conditions of 2004 and
2008.
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Figure 10 shows the change of the minimum flow cross section area below mean high water for
Section B since inlet opening. The data indicate that following inlet opening the minimum cross
section shoaled to a level similar to the 2008 conditions. After the initial post dredging
adjustment the minimum cross section area of flow, the 4 month and 7 month post dredging
conditions became larger than the conditions of 2004 and 2008. However, at 12 months post
dredging the minimum cross section dropped below the 2004 and 2008 conditions.
Figure 11 shows the change in total volume of sand accumulated in the dredge template
following inlet opening. The figure shows that over 5,500 cubic yards of sand were dredged from
Section B. Over the 12 months since dredging nearly 5,000 cubic yards have accumulated in
Section B. The amount of material accumulated in Section B after 12 months was much greater
than the 2004 and 2008 conditions. Figure 12 shows a table of the design criteria parameters for
Section B with comparisons to post dredging measurements. Recommended target values for
each parameter are shown in red.
Section C Outer Flood Shoal
Section C represents the outer(bay side) flood shoal area of Clam Bay which is also a junction in
the Clam Bay system where flow from the north and south tributaries connects to the inlet.
Restriction of this area below design levels may reduce the tidal ranges in the bay system and
therefore reduce tidal flow through the inlet. Only part of Section C was dredged in the 2013
maintenance dredging. This analysis is presented in part based upon the dredged portion of
Section C and in part based upon the entirety of Section C.
Figure 13 shows the change of average flow cross section area below mean high water for the
dredged portion of Section C in 2013. The figure covers the time period from January 2013 to 12
months post dredging. This illustrates pre-dredging conditions when the inlet was closed, how
the average cross section evolved immediately following dredging, 4 months, 7 months, and 12
months post dredging. The figure also shows the 2008 average cross section area and the design
template area dredged in 2013. The data indicate that since Section C was partially dredged the
average cross section remained below the 2008 conditions. The data also shows that the average
cross section area in the dredged portion of Section C was similar to the 2008 conditions at 7
months post dredging and approached pre-dredging conditions at 12 months post dredging.
Figure 14 shows the change of the minimum flow cross section area below mean high water for
all of Section C following inlet opening. The data indicate that since Section C was partially
dredged the average cross section generally remained below the 2004 and 2008 conditions.
Figure 15 shows the change in total volume of sand accumulated in the dredged portion of
Section C since inlet opening. The figure shows that over 2,000 cubic yards of sand were
dredged from Section C. Over the 12 month period since dredging, approximately 1,500 cubic
yards have accumulated in Section C. The accumulated material in the dredged portion of
Section C is greater than the conditions of 2004 and 2008.
Figure 16 shows the change in total volume of sand in all of Section C including the part that
was not dredged in 2013. This figure illustrates the relative amount of dredging to the total
volume within the template. The figure also shows the volumes within the template for 2004 and
2008 conditions.
Figure 17 shows a table of the design criteria parameters for Section C with comparisons to post
dredging measurements. Recommended target values for each parameter are shown in red.
Fig 10
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Inlet Channel Length
The channel length is an important factor in the inlet stability parameters. A longer inlet channel
will provide greater resistance to flow. Higher flow resistance will reduce the tidal range and
increase the phase lag with the gulf tide which reduces the tidal prism and flow through the inlet.
Figure 18 shows a selection of aerials showing Clam Pass from 2004 to 2013. The figure shows
the range of channel orientation and change in channel length and beach width on both sides of
the inlet during that period.
Figure 19 shows a plot of the approximate channel length measured at the center line of the
channel through Section A from open coast to the beginning of Section B. The plot shows the
dredged channel length of approximately 250 feet. Pre-dredging conditions show a channel
length of over 500 ft. The data shows the channel in Section A meandered to over 600 feet in
length before the inlet closed in 2012.
Figure 20 shows a table of the design criteria parameters for channel length with comparisons to
post dredging measurements and mapping of the channel evolution since reopening in April
2013. The recommended target value for channel length is shown in red.
A similar situation also occurs in Sections B and C. After dredging, these Sections behave as
bay areas where sand may accumulate. As sand accumulates these areas become channelized.
This channelization increases the overall channel length and adds to the flow resistance and
attenuation of the bay range. When the flood shoal areas fill to capacity, the connection between
the gulf and bay become a very long meandering channel that dissipates the tidal range and
diminish the flow rate beyond critical conditions needed to keep the inlet open. Such conditions
existed in the late nineties and in 2012 prior to inlet closure. Maintenance dredging of Sections B
and C as conducted in 1999, 2002, 2007 and partially in 2013 is necessary to keep the inlet
stable.
Ebb shoal
The size and shape of the ebb shoal is a key factor to the stability of the inlet that supports the
stability of the system. The ebb shoal helps to keep the inlet open when facing storms and big
wave events. The ebb shoal delta provides sheltering to the channel and sand bypass pathway
around the inlet without filling it closed. The shape and volume of the ebb shoal are additional
indicators of the stability of the inlet. Ebb shoal critical conditions include onshore collapse of
the ebb shoal that can be indicated by significant change in ebb shoal offshore distance, volume,
and increase in dry beach areas adjacent to the inlet.
Figure 21 shows a table for the ebb shoal design criteria parameters and monitoring
measurements
since inlet opening in April 2013. Recommended target values for the ebb shoal are presented in
red.
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Pelican Bay Services Division
May 30, 2014
Ver. 6.2
EXHIBITS
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