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Landscape Changes

Landscape Changes

Landscape Changes are alterations of the natural landscape through human activities, including coastal development, shoreline armoring, impervious surfaces, deforestation, or soil disturbance, which can alter water flow patterns and lead to pollutant runoff into coastal systems.

CMap

Applied chemicals are chemicals applied to lands, vehicles, buildings, or during manufacturing for a variety of purposes, including maintaining pests, improving soil quality, or cleaning surfaces. Atmospheric Emissions include discharges of atmospheric pollutants, including mercury, greenhouse gases, nitrogen and sulfur dioxides, and volatile organic compounds from the operation of factories, vehicles, and other sources. Biological Addition refers to anthropogenic inputs of a biological nature into the reef ecosystem, including artificial habitat, domestic animal waste, supplemental feeding, and escape or release of non-native species. Biological Harvest is the collection of living things from the ecosystem for recreation, consumption, or sale of marine products. Coastal Development is the construction of infrastructure, buildings, homes, and roads in coastal communities. Contact Uses, such as biological additions, physical damage, and biological harvesting, are activities in which humans create pressures through direct contact with the ecosystem. Cultural services are the nonmaterial benefits people obtain from ecosystems through spiritual enrichment, cognitive development, recreational opportunities, aesthetic experiences, sense of place, and educational and research opportunities. Deforestation and Devegetation are the removal of trees and plants, including clear-cutting, to provide clear land for farms, roads, homes, buildings, and other infrastructure. Discharge limitations are responses to regulate and control the discharge of pollutants and the use of chemicals. Discharges are the intentional or unintentional distribution of chemicals, debris, or other pollution, into the environment as a consequence of human activities. Ditching & Soil Disturbance pertains to large-scale changes to the terrestrial landscape through channeling for irrigation, grading for roads & construction, and mining which disrupt and dislodge soil and can lead to sediment runoff into the watershed. Ecosystem services are the benefits people obtain from ecosystems . Impervious surfaces are surfaces, such as asphalt roads and concrete sidewalks. Landscape Changes are alterations of the natural landscape through human activities, including coastal development, shoreline armoring, impervious surfaces, deforestation, or soil disturbance, which can alter water flow patterns and lead to pollutant runoff into coastal systems. Landuse management pertains to responses that determine the use of land for development and construction. Littering is a type of pollution that occurs when garbage, including plastics, paper, and metal, are not disposed of properly and can enter coastal waters. The Reef Ecosystem includes a suite of abiotic variables that form the physical and chemical environment. Physical Damage to reef habitat and wetlands can occur from vessel groundings, dredging, trampling, boat movement, anchor drops, trawling, and fishing gear. Pressures are human activities that create stress on the environment. Provisioning services are the products or ecosystem goods obtained from ecosystems, including seafood, genetic and biochemical resources, pharmaceuticals, ornamental resources, and water resources. The state of the Reef Ecosystem is the condition, in terms of quantity and quality, of the abiotic and biotic components including physical, chemical, and biological variables. Reef Life is the abundance, distribution, and condition of the biological components of the coral reef ecosystem. Regulating Services are benefits obtained from ecosystem processes that regulate the environment, including erosion regulation, natural hazard regulation, and climate regulation. Resource use management pertains to responses to regulate or limit contact activities that may directly impact coastal species through harvesting or physical damage. Responses are actions taken by groups or individuals in society and government to prevent, compensate, ameliorate or adapt to changes in Ecosystem Services or their perceived value. Shoreline armoring is the construction of bulkheads, seawalls, riprap or any other structure used to harden a shoreline against erosion. Socio-Economic Drivers include the sectors that fulfill human needs for Food & Raw Materials, Water, Shelter, Health, Culture, and Security, and the Infrastructure that supports the sectors. Supporting services are ecological processes that indirectly benefit humans by maintaining a functional ecosystem for the production of other ecosystem goods and services. Waterborne discharges include direct and indirect discharges of pollutants into the aquatic environment, including chemicals, nutrients, sediment, and pathogens.

CMap Description

Landscape changes are driven by coastal development and the need for housing and infrastructure that depend on civil engineering and construction, as well as transportation projects. Economic growth in cultural sectors, such as tourism and recreation or fishing, may drive local population growth of residents or increase numbers of visitors. Landscape changes, including impervious surfaces, devegetation, shoreline armoring, dredging, or filling for construction of roads and buildings, can alter rates of pollutant runoff, directly impact coastal vegetation, and alter patterns of water flow. Many of the same socio-economic sectors that drive landscape changes also benefit from reef ecosystem services, including aesthetic value, seafood, and shoreline protection. Construction codes and regulations, transportation policies, agriculture policies, and landuse management through planning, permitting, and zoning can influence intensity and distribution of landscape changes. Dredging regulations can be used to limit impacts to coastal wetlands.

Citations

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Citation Year Study Location Study Type Database Topics

Management Options

Management Option Description Sources Database Topics
Agriculture & Aquaculture: Hydroseeding High Risk Soils Hydroseeding is a process that creates a slurry of seeds, water, and mulch. This slurry can be applied with the use of trucks, trailers, and even aircrafts. This method is particularly useful because it promotes quick germination and reduces erosion. It is especially beneficial to use this method where there is a vastness of bare soil due to clearing vegetation for roads, homes, and farming. Higher elevations are typically steeper and often experience heavy rainfall, and ultimately an extreme amount of erosion occurs if soil is bare. Erosion from the highlands can fill the reservoirs in the drainage basin with sediment. Using hydroseeding would increase vegetation and ultimately the stabilization of the soil. Also, increased vegetation through hydroseeding would help with infiltration rates because the roots would aerate the soil. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 1999. Temporary Seeding. NRCS Planning and Design Manual. U.S. Depatrment of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Biological Monitoring & Restoration; Civil Engineering & Construction; Construction Codes & Projects; Deforestation & Devegetation; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Food & Energy Policies; Food & Raw Materials; Forestry; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Mining; Mining Policies; Reef Life; Sediment
Agriculture & Aquaculture: Change Agricultural Cover Crop Practices Cover crop outreach entails changing agricultural practices in an area to leave vegetation and cover on the soil while growing other crops (e.g. Coffee). Agricultural practices that encourage leaving soil bare are extremely susceptible to erosion (e.g. sun grown Coffee). Cover crop methods and shade-grown crops (e.g. shade-grown Coffee) would reduce the large amount of sediment that is eroding, particularly from high elevations, and ultimately will reduce the amount of sediment that reaches the coral reefs. Options to encourage transition to cover crop practices include outreach to raise awareness of benefits and cost share programs to help farmers with the burden of the extra expense. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. 2010. Conservation Cover. CODE 327. US Department of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Applied Chemicals; Collaboration & Partnering; Cultural Policies; Deforestation & Devegetation; Discharges; Ditching & Soil Disturbance; Environmental Education & Outreach; Food & Energy Policies; Food & Raw Materials; Funding & Donations; Landscape Changes; Non-point Source Controls; Non-point Source Runoff; Responses; Sediment
Agriculture & Aquaculture: Contour Farming Contour Farming involves sloping land in such a way that field preparation, planting and cultivating are done on the contour. This includes following established grades of terraces or diversions. During heavy rains the crop rows formed slow water runoff reducing erosion and water runoff of non-point source pollutants such as agricultural herbicides and fertilizers. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Applied Chemicals; Discharge Limitations; Ditching & Soil Disturbance; Fertilizer & Pesticide Use; Food & Energy Policies; Food & Raw Materials; Food, Beverage, & Tobacco Products; Landscape Changes; Non-point Source Controls; Non-point Source Runoff; Nutrients; Sediment; Toxics; Waterborne Discharges
Agriculture & Aquaculture: Fertilizer Application Management This agricultural best management practice involves the development, implementation and periodic update of nutrient management plans. Nutrient management plans are used to efficiently apply nutrients at appropriate rates so as to still achieve desired crop yields. There are several important measures and considerations that must be taken before developing the nutrient plan. Farm and field maps, yield expectations, nutrient resources, and geologic field limitations are all important. Some crops fix nitrogen, such as legumes, and have a nitrogen credit that must be factored. Field limitations include shallow aquifers, nearby surface water, sinkholes, and highly erodible soils. If the nutrients to be applied aren�t commercial they must be assessed to determine the nutrient value and the rate of availability of the nutrients. The nutrient plan�s timing and application methods should use the limiting nutrient concept and avoid applications to frozen soil and during periods of leaching or runoff. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Jokela, Bill, Peter Kleinman, John Peters, and Ann Wolf,. 2011. Manure Spreader Calibration & Manure Testing.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Applied Chemicals; Chemical Use Regulations; Discharge Limitations; Fertilizer & Pesticide Use; Food & Energy Policies; Food & Raw Materials; Food, Beverage, & Tobacco Products; Landscape Changes; Non-point Source Controls; Non-point Source Runoff; Nutrients; Waterborne Discharges
Agriculture & Aquaculture: Grazing Land Management This management option protects range, pasture and other types of grazing lands for agricultural animals. Special actions should be taken to protect sensitive areas such as streams, wetlands and estuaries if livestock is to have access to these areas. Grazing management practices can be categorized into four types, vegetative stabilization, grazing management systems, access limitations and alternative water supplies. Vegetative stabilization involves reestablishing the vegetative cover on ranges after it has been removed by grazing to reduce erosion rates. Grazing management systems typically reduce the time livestock spend in each pasture to increase the quantity and quality of vegetation in those pastures. Grazing frequency, timing, duration, area allocation, and livestock distribution kind, class, distribution and stocking rates should all be considered in the management system to ensure adequate pasture rehabilitation. Access limitations, such as fencing and stream crossings are used to herd and control livestock movement. Physical disturbance from livestock can increase erosion, so crossings and watering access points should be hardened. Alternative water supplies are an alternative to more sensitive water sources that may be vulnerable to erosion and discharges from grazing areas. Environmental Protection Agency Office of Water. 1993. Guidance Specifying Management Measures For Sources Of Nonpoint Pollution In Coastal Waters. EPA/840/B-92/002, US EPA, Washington, DC.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Deforestation & Devegetation; Discharges; Food & Energy Policies; Food & Raw Materials; Food, Beverage, & Tobacco Products; Landscape Changes; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Nutrients; Physical & Chemical Water Quality Criteria; Sediment; Waterborne Discharges
Agriculture & Aquaculture: Sodic Soil Management In coastal agriculture it is important to manage and reduce accumulations of salts on the soil surface and down to the crop rooting depth. Saline seep often occurs in crop areas where the water table is very shallow. Irrigation management or drainage improvements may be necessary. Another option may be subsoiling, where internal soil drainage is restricted by layers of contrasting permeability and soil moisture levels are low enough to allow shattering and mixing of soil layers. Vegetative measures include planting deep rooted crops such as wheatgrass and alfalfa. Soil amendments can be used to treat sodium, displacing it with calcium depending on the specific chemistry of the soil. Though crop yield does not directly impact coral reefs, ground water restoration projects may change the raise the water table, making sodic soil management important. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Coastal Development; Ditching & Soil Disturbance; Food & Raw Materials; Landscape Conservation & Restoration; Salinity; Surface & Groundwater Flow; Water Depth & Sea Level
Corporate Response: Develop Outreach with Local Businesses Information should be provided to business along the water so that employees will be aware of environmentally sensitive business practices. This can be achieved through informative brochures, and distributing other educational materials. These interactions can also be used to inform businesses of opportunities for voluntary certifications (#104). NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

The Coral Reef Alliance (CORAL) the Tour Opperators' Iniative (TOI) and The Center for Environmental Leadership in Business (CELB). 2003. A Practical Guide to Good Practice: Managing Environmental Impacts In The Marine Recreation Sector.

Coastal Development; Collaboration & Partnering; Corporate Responses; Cultural Policies; Entertainment & Accommodation Services; Environmental Education & Outreach; Golf Course Operations; Hotel & Food Services; Infrastructural Policies; Manufacturing & Trade; Wholesale & Retail Trade
Damage Assessment, Documentation & Response: Respond to Natural Resource Injuries from Coastal Construction & Development This involves assessing coral, seagrass, and hard bottom substrate that is impacted during coastal construction repair or alternation. If unacceptable damages are occurring this information will be useful in future permit decision making. If infringements have occurred, this information may be useful for compensatory mitigation and liability for restoration of those natural resources injured. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Monitoring & Restoration; Civil Engineering & Construction; Coastal Development; Coastal Engineering; Construction Codes & Projects; Docks & Marinas; Dredging Regulations; Dredging, Draining, & Filling; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Impervious Surfaces; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Mangroves; Mitigation; Permitting & Zoning; Physical Damage; Physical Variables; Ports & Harbors; Reef Habitat; Remediation; Resource Use Management; Seagrasses; Shoreline Armoring; Special Use Permitting; Utilities; Utility Line Construction & Maintenance; Wetland & Reef Restoration; Wetlands
Data Management & Decision Tools: Develop a Geographic Information System Incorporating Satellite and Aerial Images This option involves the acquisition of high-resolution, low altitude photos of management areas and grounding hotspots. These photos can then be used for baseline documentation for natural resource litigation, research, and management decisions. If these images are to be incorporated into larger geodatabase, such as that proposed in # 166, a standardized protocol should be developed in advance, as suggested in management option #166. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Monitoring & Restoration; Biological Monitoring, Mapping, & Scientific Research; Cultural Services; Decision Support; Discharges; Ecosystem Monitoring & Restoration; Ecosystem Services; Educational & Research Opportunities; Landscape Changes; Landscape Conservation & Restoration; Physical Damage; Resource Use Management; Security & Public Administration Policies
Discharge Controls: Carbon Sequestration Carbon sequestration is the process through which practices remove carbon dioxide (CO2) from the atmosphere. The term "sink" is also used to describe agricultural and forestry lands that absorb CO2, the major global warming gas emitted by human activities. Agricultural and forestry practices can also release CO2 and other greenhouse gases to the atmosphere. In the ocean, phytoplankton are another major carbon sink. Houghton, R.A. 2002. Magnitude, distribution and causes of terrestrial carbon sinks and some implications for policy. Climate Policy 2:71-88.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Algae; CO2; Deforestation & Devegetation; Forestry; Funding & Incentives; Greenhouse Gas Emissions; Infrastructure; Landuse Management; Plankton; Political Pressure; Solid Waste Disposal
Forestry Policy: Forestry Streamside Management Areas There are often surface waters, such as streams and lakes, within forestry areas that require special protection. This management option involves establishing and maintaining management areas (35 to 50 feet) around these surface waters to buffer against changes in temperature, increases in sediments and nutrients, and to provide bank stability. Canopy species in these areas also provide woody debris needed for instream channel structure and aquatic species habitat. Environmental Protection Agency Office of Water. 1993. Guidance Specifying Management Measures For Sources Of Nonpoint Pollution In Coastal Waters. EPA/840/B-92/002, US EPA, Washington, DC.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture, Aquaculture, & Forestry Policies; Carbon Storage & Cycling; Civil Engineering & Construction; Construction Codes & Projects; Deforestation & Devegetation; Discharges; Ditching & Soil Disturbance; Food & Raw Materials; Forestry; Impervious Surfaces; Infrastructural Policies; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Non-point Source Runoff; Point & Mobile Source Controls; Primary Production; Sediment; Surface & Groundwater Flow; Waterborne Discharges; Wood, Plastics, & Chemical Products
Forestry Policy: Forestry Management Planning There are many aspects to properly managing forestry sites to reduce point source and non-point source pollutants. Forestry activities can degrade water quality with several types of pollutants and impacts, including: sediment, nutrients, forest chemicals like pesticides, organic debris from tree litter, increased water temperature and increased streamflow. The Forestry management plan and practices include, but are not limited to: pre-harvest planning, road construction and use, prescribed burning and fire management, brush management, timber harvest, regeneration, and application of forest chemicals. Wetlands Forest Management has additional best practices. Environmental Protection Agency Office of Water. 1993. Guidance Specifying Management Measures For Sources Of Nonpoint Pollution In Coastal Waters. EPA/840/B-92/002, US EPA, Washington, DC.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture, Aquaculture, & Forestry Policies; Applied Chemicals; Biological Harvest; Chemical Use Regulations; Civil Engineering & Construction; Deforestation & Devegetation; Discharge Limitations; Ditching & Soil Disturbance; Fertilizer & Pesticide Use; Food & Raw Materials; Forestry; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Manufacturing & Trade; Non-point Source Controls; Non-point Source Runoff; Nutrients; Physical & Chemical Water Quality Criteria; Point & Mobile Source Controls; Point Source Discharges; Regulating Services; Resource Use Management; Sediment; Supporting Services; Surface & Groundwater Flow; Toxics; Waterborne Discharges; Wetlands; Wood, Plastics, & Chemical Products
Injury Prevention: Foster Reef Resilience Resilience relates to how well the reef ecosystem is able to maintain key functions and processes while under abnormal pressure or stress. Two ways of supporting coral reef resilience are: incorporating known resilient areas into management design and by implementing strategies to either reinstate or protect factors that contribute to resilience, such as good environmental conditions, biological diversity, and connectivity. Marshall, P. and H. Schuttenberg. 2006. A reef manager's guide to coral bleaching.

Biological Monitoring & Restoration; Contact Uses; Coral; Decision Support; Discharges; Ecosystem Monitoring & Restoration; Landscape Changes; Marine Protected Areas; Pressures; Resource Use Management
Landuse Management: Temporary Road Planning and Construction This management option involves minimizing sediment discharges from forestry and other temporary roads through their planning and construction. Since these roads are seasonal or temporary, less time and effort is normally invested in construction. Road construction has four main phases, clearing, leveling, construction and surfacing. Construction timing should be targeted to avoid sensitive spawning periods and during low stream flow at water passes. Road surface drainage shaping requires proper moisture content, surfacing, and grading. Drainage should be installed to reduce the volume and velocity of runoff water passing over sensitive areas. Methods for road surface drainage include: broad-based dip construction, pole culverts, ditch relief culverts, road outsloping and grading, ditch and turnout construction. Roadway runoff should be prevented from flowing directly into watercourses by using turnouts, wing ditches and dips. Brush barriers, silt fences, riprap and filter strips can be used to trap sediment in runoff water. Where roads cross streams it is important to guard against erosion, as such erosion may necessitate road repairs. Environmental Protection Agency Office of Water. 1993. Guidance Specifying Management Measures For Sources Of Nonpoint Pollution In Coastal Waters. EPA/840/B-92/002, US EPA, Washington, DC.

Agriculture, Aquaculture, & Forestry Policies; Civil Engineering & Construction; Construction Codes & Projects; Decision Support; Deforestation & Devegetation; Discharge Limitations; Discharges; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Food & Raw Materials; Forestry; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Infrastructure; Land & Air Transportation; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Mining; Mining Policies; Non-point Source Controls; Non-point Source Runoff; Nutrients; Road Construction & Maintenance; Sediment; Transportation; Transportation Policies
Landuse Management: Mine Reclamation Lands disturbed by mining must be reclaimed to their Approximate Original Contour (AOC). Mine operators must backfill, compact, and grade in order to restore the AOC of the land with all highwalls, spoil piles, and depressions eliminated. Spoil material is prone to erosion, and may carry various disturbed toxics into groundwater if not properly managed. Temporary roads and impervious surfaces may have also been constructed for mining purposes. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Office of Surface Mining Reclamation and Enforcement. POSTMINING LAND USE: Exceptions to Approximate Original Contour Requirements for Mountaintop Removal Operations and steep Slope Mining Operations. Washington, DC.

Chemical Use Regulations; Civil Engineering & Construction; Coal Mining; Construction Codes & Projects; Decision Support; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Environmental Monitoring, Mapping, & Scientific Research; Food & Raw Materials; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Manufacturing & Trade; Manufacturing & Trade Policies; Mineral, Rock, & Metal Mining; Mining; Mining Policies; Mitigation; Non-point Source Controls; Non-point Source Runoff; Physical & Chemical Water Quality Criteria; Political Pressure; Remediation; Resource Use Management; Sediment; Surface & Groundwater Flow; Toxics; Valuation; Waterborne Discharges
Landuse Management: Household Landscaping Best Management Practices Homeowners manipulate the visible features of the land surrounding their home through landscaping. This includes flora, fauna, and terrain. Best Management Practices (BMPs) for landscaping include selection of indigenous flora and fauna, landscape irrigation (sprinkler systems etc), stormwater runoff BMPs, reducing water use, integrated pest management, composting, and incorporation of permeable surfaces. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Irrigation Association. 2010. Turf and Landscape Irrigation Best Management Practices.

Applied Chemicals; Biological Addition; Building & Home Construction; Chemical Variables; City Planning; Discharge Limitations; Environmental Education & Outreach; Escape & Release of Non-natives; Existence Value & Sense of Place; Fertilizer & Pesticide Use; Impervious Surfaces; Landscape Conservation & Restoration; Landscaping & Household Services; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Nutrients; Sediment; Shelter; Supplemental Feeding; Toxics; Waterborne Discharges
Marine Zoning: Permitting Application & Award This management approach is important because permits assure protection and conservation of coral resources from harmful activities and practices. Within sanctuary waters, special use permits (#157) can be used to allow scientists and others to conduct necessary work while following permitting regulations to reduce the impact of that work. General permits are often required for altering land-use, construction projects and certain discharges. To be eligible for a permit, the operator may be required to conduct impact assessments, institute best management practices and conduct monitoring of the project. Though permits are a necessary precaution, the process can be streamlined through ensuring clear submittal requirements, and reducing redundancy. Redundancy often occurs when multiple agencies must approve a permit, a single point of contact and standard, inter-agency protocols can reduce unnecessary redundancy. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Addition; Biological Harvest; Building & Home Construction; Coastal Development; Collaboration & Partnering; Cultural Policies; Discharges; Dredging, Draining, & Filling; Impervious Surfaces; Land-Based Civil Engineering; Landscape Changes; Landuse Management; Permitting & Zoning; Physical Damage; Point Source Discharges; Public Administration; Resource Use Management; Scientific Research; Security & Public Administration Policies; Special Use Permitting
Marine Zoning: Utilize Marine Protected Areas for Research and Monitoring Research and monitoring of marine protected areas determine the degree to which the zones meet goals and objectives for protecting natural resources, as well as human-use patterns, attitudes and compliance. Once data is gathered from within the protected zone it can than be compared to comprable data from outside the protected zone, as a control. It is necessary to compile and review data on use patterns to determine where additional Special-Use Areas would be appropriate. Research in the protected area should be non-invasive. It is important to make the protected area available for external research as well. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Harvest; Biological Monitoring & Restoration; Biological Monitoring, Mapping, & Scientific Research; Collaboration & Partnering; Contact Uses; Decision Support; Designated Uses; Discharges; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Environmental Monitoring & Restoration; Fish; Invasive Species; Invertebrates; Landscape Changes; Marine Protected Areas; Marine Vertebrates; Permitting & Zoning; Physical Damage; Resource Use Management; Special Use Permitting; Wetlands
Marine Zoning: Sanctuary Preservation Areas (SPAs) This is a type of Marine Zoning used by the Florida Keys National Marine Sanctuary (FKNMS). SPAs focus on the protection of shallow, heavily used reefs where conflicts occur between user groups, and where concentrated visitor activity leads to resource degradation. They are designed to enhance the reproductive capabilities of renewable resources, protect areas critical for sustaining and protecting important marine species, and reduce user conflicts in high-use areas. This is accomplished through a prohibition of consumptive activities within these areas. They have been chosen based on the status of important habitat, the ability of a particular area to sustain and protect the habitat, the level of visitor use, and the degree of conflict between consumptive and non-consumptive users. The actual size and location of these zones have been determined by examination of user patterns, aerial photography, and ground-truthing of specific habitats. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Accidental & Illegal Harvest; Anchoring & Vessel Grounding; Aquaculture; Aquarium & Pet Trade; Aquarium Stock; Artisanal Fishing; Beaches & Nature Parks; Biological Addition; Biological Harvest; Biological Monitoring & Restoration; Boat Movement; Boating Activities; Boating Regulations; Coastal Defense; Coastal Development; Coastal Engineering; Commercial Fisheries; Commercial Fishing Boats; Complex Habitat & Resources; Cruise Ships; Cultural Services; Decision Support; Designated Uses; Dive, Snorkeling, & Swimming Tourism; Dredging Regulations; Dredging, Draining, & Filling; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Entertainment & Accommodation Services; Environmental Monitoring & Restoration; Finfish & Shellfish Stock; Finfish Harvest; Fisheries & Hunting Policies; Fishing & Harvesting Management; Fishing Sector; Invertebrate Harvest; Landscape Changes; Large Ships; Live Collection; Marine Protected Areas; Oil & Gas Tankers; Ornamental Jewelry & Art; Permitting & Zoning; Physical Damage; Public Administration; Recreational Fishing; Recreational Opportunities; Resource Use Management; Security; Small Boats; Souvenir & Decorative Trade; Supporting Services; Tourism & Recreation; Tourism & Recreation Policies; Trampling; Travel Services & Tour Operators; Trawling & Fishing Gear Damage; Water Resources; Water Transportation
Monitor & Research: Research and Monitor Wetlands This management option involves monitoring and research of mangroves, both for biotic and abiotic factors. Some biotic factors include disease, species, invasive species, abundance, age and leaf litter. Important abiotic factors include sedimentation rates, types and causes of turbidity, and soil chemistry. The activity would document changes to the extent of mangrove vegetation by using historical aerial photography and other records. Wetland nutrient and contaminant processing productivity depends on maintaining a balance and not exceeding thresholds. There remain many unknowns in wetland restoration as to optimal capacity and how to achieve this. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Monitoring & Restoration; Biological Monitoring, Mapping, & Scientific Research; Carbon Storage & Cycling; Chemical Variables; Climate Regulation; Complex Habitat & Resources; Deforestation & Devegetation; Discharges; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Environmental Monitoring & Restoration; Environmental Monitoring, Mapping, & Scientific Research; Invasive Species; Mangroves; Nutrient & Contaminant Processing; Nutrients; Physical & Chemical Water Quality Criteria; Physical Variables; Primary Production; Regulating Services; Scientific Research; Seawater Flow; Sediment; Shoreline Protection; Substrate; Supporting Services; Surface & Groundwater Flow; Wetland & Reef Restoration; Wetlands
Monitor & Research: Develop Innovative Monitoring Tools This management option calls for identifying and evaluating monitoring tools and methodologies used to detect pollutants and identify cause-and-effect relationships among water quality and biological resources. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Biological Monitoring & Restoration; Chemical Variables; Contact Uses; Decision Support; Discharge Limitations; Discharges; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Environmental Monitoring & Restoration; Landscape Changes; Nutrients; Physical Variables; Reef Habitat; Reef Inhabitants; Scientific Research; Toxics
Monitor & Research: Research Historical Hydrology This activity involves a historical assessment of the hydrology of the surrounding water area around the sanctuary as it has affected water quality and biological communities within the sanctuary. It will clarify the role of freshwater inflows and water quality from local freshwater bodies. Also, this activity will examine the effects of structural modification and changes in quality, quantity, timing and distribution of freshwater releases from existing structures and will examine land-based practices affecting the water quality of runoff. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Applied Chemicals; Chemical Variables; Coastal Development; Coastal Engineering; Dam Construction & Maintenance; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Dredging, Draining, & Filling; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Environmental Monitoring, Mapping, & Scientific Research; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Landscape Changes; Landuse Management; Physical Variables; Salinity; Seawater Flow; Shoreline Armoring; Stormwater Management; Surface & Groundwater Flow; Water; Water Depth & Sea Level; Water Transportation; Waterborne Discharges
Monitor & Research: Adaptive Management By definition, adaptive management is a structured management approach that links science to decision-making, thereby improving the probability of restoration success. It provides an efficient process to address risk and uncertainty inherent within ecosystem restoration by encouraging flexible plans and designs. Monitoring (#) is an important component of adaptive management. The affect of different restoration alternatives can be seen using monitoring data, and compared against other environmental variables to determine what the best future actions are based on results of previous projects. CERP Committee. 2006. Comprehensive Everglades Restoration Plan Adaptive Management Strategy.

Artificial Habitat; Biological Addition; Biological Monitoring & Restoration; Biological Monitoring, Mapping, & Scientific Research; Chemical Variables; Decision Support; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Environmental Monitoring & Restoration; Environmental Monitoring, Mapping, & Scientific Research; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Physical Variables; Public Administration; Regulating Services; Remediation; Scientific Research; Supporting Services
Regulatory Review and Development: Evaluate Vessel Grounding Regulations In many areas, there are already regulations that target prop scarring to seagrasses and the seabed. Current boat grounding regulations should be evaluated to determine if additional regulations would be beneficial. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Anchoring & Vessel Grounding; Boating Activities; Boating Regulations; Coastal Development; Contact Uses; Cruise Ships; Cultural Services; Culture; Decision Support; Docks & Marinas; Dredging Regulations; Physical Damage; Ports & Harbors; Recreational Fishing; Recreational Opportunities; Resource Use Management; Seagrasses; Security & Public Administration Policies; Security Policies; Small Boats; Tourism & Recreation; Transportation; Water Resources; Water Transportation; Wetlands
Regulatory Review and Development: Evaluate Channel & Reef Navigation Markers This option would evaluate the need for proper marking to ensure better navigation. There are many types of markers, including buoys, charts, beacons, and GPS mapping. Such markers can also be used to advocate prohibition on vessel speeds greater than idle speed in areas designated as idle-speed only/no-wake and around shallow reef locations. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Anchoring & Vessel Grounding; Beach & Land Formation; Boat Movement; Boating Activities; Boating Regulations; Coastal Development; Contact Uses; Cultural Services; Culture; Decision Support; Designated Uses; Dive, Snorkeling, & Swimming Tourism; Dredging Regulations; Permitting & Zoning; Physical Damage; Provisioning Services; Public Administration; Recreational Fishing; Recreational Opportunities; Security & Public Administration Policies; Small Boats; Tourism & Recreation; Trampling; Transportation Policies; Water Depth & Sea Level; Water Resources; Water Transportation
Restoration: Land Reclamation Integrating Landslide Treatments This management option is exercised to prevent down slope movement of earthen materials, including natural soils, and spoil/waste from mining or forestry activities. Extreme caution and planning must be exercised before permitting any personnel, equipment or other machinery into the slide area. An experienced engineer should analyze the stability of the site both before and after alterations are made to evaluate stability. Water Control: sources of water that enter the area can be controlled to keep the material dry, as it is typically more stable when dry. Loading Control: where appropriate, consider removing excess material from upper portions of the slide area to reduce slide mass. Slope Reduction: where practice, use grading to reduce the slope of the slide area. Increasing Internal Strength: consider the impact of removing and recompacting of material at designed levels of moisture and with biotechnical slope stabilization practices. External Restraints: external restraints can be used where slope movements must be limited due to surrounding valued improvements (e.g. structures), where manipulation of the material may not achieve desired improvements. External restraints must be designed to prevent overturning, sliding at or below the base, and bearing failure of the foundation. Vegetative Treatment: deep rooted grasses and shrubs with proven performance in soil bioengineering applications can be planted using selected soil bioengineering or biotechnical slope stabilization techniques appropriate to the site. Transpiration and infiltration should be considered when choosing vegetation. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture, Aquaculture, & Forestry Policies; Construction Codes & Projects; Discharges; Ditching & Soil Disturbance; Forestry; Infrastructure; Insurance; Landscape Conservation & Restoration; Mining; Mining Policies; Non-point Source Runoff; Sediment
Restoration: Land Reclamation Integrating Toxic Discharge Controls This option aims to eliminate unsightly residues, reduce erosion and control acid or otherwise toxic aqueous discharges from abandoned coal mines, coalmine waste or other types of land change. For toxic mine drainage, preventative actions include mine sealing, infiltration control, day lighting, and neutralization with alkaline material such as hydrated lime. Which action to take relies heavily on groundwater and runoff in the region of the mine. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Aquaculture; Coal Mining; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Hydrologic Management; Mineral, Rock, & Metal Mining; Mining; Mining Policies; Non-point Source Controls; Ocean Acidity; Surface & Groundwater Flow; Toxics; Waterborne Discharges
Restoration: Beach Renourishment and Nourishment Beaches are subject to natural accretion and erosion. Tourism is often best supported by wide, accessible, public sandy beaches. Beaches can be restored to counteract natural erosion by transporting large quantities of sand onto the beach. This sand often comes from nearby dredging. Caution should be used when restoring long sections of beaches, as often the area above the mean high tide line is littoral, or privately owned, and restoration of these beaches can impact these property rights, see "Stop the Beach Renourishment, Inc. v. Florida Department of Environmental Protection (2010) U.S. Supreme Court decision." Beach protection or nourishment offers an alternative to this often expensive and abrupt type of renourishment, nourishment involves practices which encourage coastal accretion and discourage erosional forces. See "Florida's Beach and Shore Preservation Act" for some restrictions on this. NOAA Coastal Services Center. Beach Nourishment: A Guide for Local Government Officials. Coastal Services Center Accessed 6/17/2011.

Beach & Land Formation; Beaches & Nature Parks; Culture; Dredging, Draining, & Filling; Environmental Monitoring & Restoration; Landscape Conservation & Restoration; Recreational Opportunities; Shoreline Armoring; Shoreline Protection; Sunscreen Use; Tourism & Recreation
Restoration: Beach Vegatation Restoration Natural beaches are often host to important costal dune ecosystems. Due to tourism, much of the vegetation that comprises these dune ecosystems may be compromised. The natural vegetation provides an important ecosystem service, with roots providing deep stabilization against physical damage and removal of that sand. Without such vegetation sand and dunes can be completely washed away during hurricanes and other surge events. The dunes themselves offer some protection to nearby inland infrastructure during these same storm events. When the beach past the dunes is for public access it is beneficial to build raised walk-overs over the dune vegetation. This prevents trampling, which leads to dune blowouts. Natural Resources Conservation Service, editor. 2007. Native Plants for Coastal Dune Restoration: What, When, and How for Florida. US Department of Agriculture.

Beaches & Nature Parks; Biological Monitoring & Restoration; Culture; Deforestation & Devegetation; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Invasive Species; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Physical Damage; Regulating Services; Storms & Hurricanes; Tourism & Recreation; Trampling
Stormwater BMPs: Stormwater Pollution Reduction Through Instituting Preventitive Best Management Practices This method focuses on reducing the amount of harmful contaminants in stormwater runoff by establishing Best Management Practices that prevent the generation of the pollutant to begin with. These BMPs include educational programs, infrastructure improvements and agricultural BMPs. Examples of educational programs would be programs that educate the public on the importance of, and how to avoid depositing hazardous wastes, such as oil, into storm drains, or how to use landscape management controls to limit the chemical and debris that from enter stormwater runoff from their personal lawns. Infrastructure improvement could include the use of alternative turnarounds and street cleaning. Agricultural practices such as roofs and covers for pesticides and equipment, or use of bedding are both preventative stormwater practices. Some additional specific practices include: controlling fertilizer application, properly using and disposing of fertilizers, pesticides, motor oil, and other harmful chemicals, debris removal, exposure reduction, minimization of pollutants, parking lot cleaning, stormwater catch basin insert, eliminate curbs and gutters, green parking, green roofs, street design and patterns, bedding. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

US EPA. Alternative Turnarounds. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Eliminate Curbs and Gutters. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Green Parking. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Green Roofs. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Street Design and Patterns. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

Natural Resources Conservation Service. Urban BMP's - Water Runoff Management. Urban BMP's - Water Runoff Management Accessed 3/25/2011.

Irrigation Association. 2010. Turf and Landscape Irrigation Best Management Practices.

Agriculture; Applied Chemicals; Chemical Use Regulations; Chemical Variables; City Planning; Construction Codes & Projects; Discharge Limitations; Discharges; Environmental Education & Outreach; Food & Energy Policies; Food & Raw Materials; Forestry; Housing; Hydrologic Management; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landscaping & Household Services; Landuse Management; Mining; Nutrient & Contaminant Processing; Nutrients; Oil & Gas Industry; Road Construction & Maintenance; Security & Public Administration Policies; Shelter; Solid Waste Disposal; Storms & Hurricanes; Stormwater Management; Supporting Services; Toxics; Utilities; Waste Management; Waste Management Policies; Waterborne Discharges
Stormwater BMPs: Structural Stormwater Retention/Detention This method attempts to reduce the negative impacts of stormwater runoff through implementation of engineering structures that retain runoff water for further treatment or controlled release. Water collection can be selective, targeting the first flush of water, which is typically the most polluted. Water retention has the additional benefit of later release at a place and time when the water is needed (e.g. for irrigation). Rainwater Collection Systems (#11) can be an important water resource in areas where freshwater is limited. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. Combined Infiltration/Detention Basin. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Detention Devices for Dry/Wet Ponds. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Dry Extended Detention Ponds. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Leisenring, M., Clary, J., Stephenson, J., and Hobson, P. 2010. International Stormwater Best Management Practices (BMP) Database Pollutant Category Summary: Nutrients. Geosyntec Consultants, Inc.

Poresky, A., Clary, J., Strecker, E., and Earles, A. 2011. International Stormwater Best Management Practices (BMP) Database. Technical Summary: Volume Reduction. Geosyntec Consultants.

Natural Resources Conservation Service. 2010. Stormwater Runoff Controls. U.S. Depatrment of Agriculture.

Natural Resources Conservation Service. 2008. Water and Sediment Control Basin. CODE 638. U.S. Depatrment of Agriculture.

Natural Resources Conservation Service. Water Volume Management. Urban BMP's - Water Runoff Management Accessed 3/25/2011.

Agriculture, Aquaculture, & Forestry Policies; Applied Chemicals; Chemical Variables; City Planning; Civil Engineering & Construction; Climate; Coastal Development; Construction Codes & Projects; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Physical Variables; Point Source Discharges; Sediment; Shoreline Armoring; Storms & Hurricanes; Stormwater Management; Substrate; Surface & Groundwater Flow; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Water; Waterborne Discharges
Stormwater BMPs: Structural Stormwater Infiltration This management option attempts to reduce the negative impacts of stormwater runoff through implementation of engineering structures that control the volume of surface water, facilitating faster absorption of the stormwater into the ground. Often these structures are able to infiltrate larger amounts of water faster while reducing exposure to surface sediments and pollutants. Natural Resources Conservation Service. Combined Infiltration/Detention Basin. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Leisenring, M., Clary, J., Stephenson, J., and Hobson, P. 2010. International Stormwater Best Management Practices (BMP) Database Pollutant Category Summary: Nutrients. Geosyntec Consultants, Inc.

Poresky, A., Clary, J., Strecker, E., and Earles, A. 2011. International Stormwater Best Management Practices (BMP) Database. Technical Summary: Volume Reduction. Geosyntec Consultants.

US EPA. EPA Infiltration BMPs. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

Applied Chemicals; Chemical Variables; City Planning; Civil Engineering & Construction; Climate; Coastal Development; Construction Codes & Projects; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Drinking Water Supply; Fertilizer & Pesticide Use; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Irrigation; Land-Based Civil Engineering; Landscape Changes; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Point Source Discharges; Sediment; Storms & Hurricanes; Stormwater Management; Substrate; Supporting Services; Surface & Groundwater Flow; Waste Management Policies; Wastewater Discharge; Water; Waterborne Discharges
Stormwater BMPs: Rainwater Collection Systems Creating a rainwater collection system (either through policy change or the initiative of homeowners) would help in many ways. These systems would utilize water in an efficient manner. It would reduce the pressure of water as a finite resource. Water would be collected and utilized before it reaches the ground. Once rain falls to the ground, it picks up nutrients, chemicals, and pathogens on the ground and transports them in the form of runoff. Eventually this contaminated stormwater runoff enters water resources through the drainage basin. Collecting a considerable amount of water would prevent contamination of that water, and allow for it to be usable. Also, it would reduce the amount of water that is lost when it is contaminated as runoff. An overall reduced amount of stormwater runoff would reduce the amount of contaminants that would harm corals. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. Cisterns used for water harvesting. Urban BMP's - Water Runoff Management Accessed 3/18/2011.

Leisenring, M., Clary, J., Stephenson, J., and Hobson, P. 2010. International Stormwater Best Management Practices (BMP) Database Pollutant Category Summary: Nutrients. Geosyntec Consultants, Inc.

Applied Chemicals; Building & Home Construction; Chemical Variables; City Planning; Civil Engineering & Construction; Cleaner & Solvent Use; Climate; Construction Codes & Projects; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Drinking Water Supply; Fertilizer & Pesticide Use; Food & Energy Policies; Impervious Surfaces; Infrastructural Policies; Infrastructure; Irrigation; Land-Based Civil Engineering; Landscape Changes; Landscaping & Household Services; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Sediment; Shelter; Storms & Hurricanes; Stormwater Management; Substrate; Surface & Groundwater Flow; Toxics; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Water; Water Utilities Policies; Waterborne Discharges
Stormwater BMPs: Structural Stormwater Filtration This method attempts to reduce the negative impacts of stormwater runoff through implementation of engineering structures that trap or filter impurities out of runoff water. These include but are not limited to, using swales, filter strips, oil/water separators, oil/grit separators, and sand filters. Often structural retrofitting is coupled with biological filters/controls to direct water as desired and to fully reap the benefits of both systems. Structural filters are often incorporated into retention/detention and infiltration systems as well. One disadvantage of structural filters is that they are often higher maintenance as sand and chambers fill and clog with pollutants over time. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Natural Resources Conservation Service. Compost Filter System. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Dry Swale. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Median Strip Infiltration Trench. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Montgomery County Water Quality Inlet. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Off-Line Infiltration Basin. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Oil/Water Separators. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Organic Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Peat Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Perimeter Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Pocket Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Rockville Water Quality Inlet. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Sediment Basin (Water Quality Enhancement). Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Side-by-Side Infiltration Basin. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Surface Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Underground Sand Filter. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Underground Trench with Oil/Grit Chamber. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Under-the-Swale Infiltration Trench. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Water Quality Volume (WQV) Storage Tank. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Water Environment Research Foundation, American Society of Civil Engineers, U.S. Environmental Protection Agency, Federal Highway Administration, American Public Works Association, editor. 2008. Overview of Performance by BMP Category and Common Pollutant Type. International Stormwater Best Management Practices (BMP) Database [1999-2008].

Leisenring, M., Clary, J., Stephenson, J., and Hobson, P. 2010. International Stormwater Best Management Practices (BMP) Database Pollutant Category Summary: Nutrients. Geosyntec Consultants, Inc.

US EPA. EPA Filtration BMPs. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Manufactured Products for Stormwater Inlets. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

US EPA. Alum Injection. National Pollutant Discharge Elimination System Menu of BMPs Accessed 3/25/2011.

Natural Resources Conservation Service. 2010. Stormwater Runoff Controls. U.S. Depatrment of Agriculture.

Natural Resources Conservation Service. 2005. Solid/liquid Waste Separation Facility. U.S. Depatrment of Agriculture.

Applied Chemicals; Chemical Variables; City Planning; Civil Engineering & Construction; Coastal Engineering; Construction Codes & Projects; Dam Construction & Maintenance; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Food & Energy Policies; Hydrologic Management; Impervious Surfaces; Improved Technology; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Road Construction & Maintenance; Sediment; Storms & Hurricanes; Stormwater Management; Surface & Groundwater Flow; Toxics; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Waterborne Discharges
Stormwater BMPs: Sustained Reservoir Minimum Release of Minimum Baseflow to Sustain Aquatic Habitat In some regions, even high intensity rivers (e.g. Rio Loco, Puerto Rico) are seasonal, drying for long enough to kill aquatic vegetation. Creating a constant baseflow would help sustain aquatic life and ultimately help to process nutrients. High intensity rivers are already prone to extreme channel erosion from the high flow rates, this erosion is even greater without any benthic biota to hold sediment on the river bottom. Restricting the release of reservoir water to that required to maintain aquatic biota would reduce the intensity of flow, stabilize the river bottom, create habitat and naturally process nutrients that could potentially contribute to eutrophication out on the coral reef. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Algae; Biological Monitoring & Restoration; Climate; Dam Construction & Maintenance; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Drinking Water Supply; Ecosystem Monitoring & Restoration; Hydrologic Management; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landuse Management; Nutrient & Contaminant Processing; Physical Variables; Point Source Discharges; Pressures; Primary Production; Reef Habitat; Reef Life; Regulating Services; Storms & Hurricanes; Stormwater Management; Surface & Groundwater Flow; Utilities; Waste Management; Water; Waterborne Discharges; Wetland & Reef Restoration; Wetlands
Stormwater BMPs: Biological Stormwater Filtration This method attempts to reduce the negative impacts of stormwater runoff through implementing engineering techniques that allow natural processes and plants to act as filters. Such techniques would include using grass parking and turf covered swales. Many of these techniques, such as reversed elevations for planted areas in parking lots, can demonstrate benefits both as natural filters and for the vegetation that are used since it eliminates the need to water them with irrigation systems. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. Basic Biofiltration Swale. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Bioretention System. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Constructed Wetland. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Filter Strips. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Reversed Elevations System for Parking Lots and Planting Areas. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Riparian Forest Buffer. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Roadway Landscape Treatment System. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Wet Biofiltration Swale. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Wet Pond Design. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Natural Resources Conservation Service. Wet Swale. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Water Environment Research Foundation, American Society of Civil Engineers, U.S. Environmental Protection Agency, Federal Highway Administration, American Public Works Association, editor. 2008. Overview of Performance by BMP Category and Common Pollutant Type. International Stormwater Best Management Practices (BMP) Database [1999-2008].

Leisenring, M., Clary, J., Stephenson, J., and Hobson, P. 2010. International Stormwater Best Management Practices (BMP) Database Pollutant Category Summary: Nutrients. Geosyntec Consultants, Inc.

Applied Chemicals; Building & Home Construction; Chemical Variables; City Planning; Civil Engineering & Construction; Climate; Construction Codes & Projects; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Fertilizer & Pesticide Use; Golf Course Operations; Impervious Surfaces; Infrastructure; Irrigation; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landscaping & Household Services; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Nutrient & Contaminant Processing; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Primary Production; Road Construction & Maintenance; Sediment; Storms & Hurricanes; Stormwater Management; Substrate; Supporting Services; Surface & Groundwater Flow; Toxics; Utilities; Waste Management; Waste Management Policies; Wastewater Discharge; Water; Waterborne Discharges
Stormwater BMPs: Biological Stormwater Retention/Detention This method attempts to reduce the negative impacts of stormwater runoff through implementation of natural structures that retain runoff water for further treatment or controlled release. These structures are typically characterized as retention ponds and incorporate natural vegetation such as grass. These ponds may be dry, or may drain into nearby wetlands. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. Dry Extended Detention Ponds. Urban BMP's - Water Runoff Management Accessed 3/23/2011.

Poresky, A., Clary, J., Strecker, E., and Earles, A. 2011. International Stormwater Best Management Practices (BMP) Database. Technical Summary: Volume Reduction. Geosyntec Consultants.

Applied Chemicals; Chemical Variables; City Planning; Civil Engineering & Construction; Discharge Limitations; Discharges; Hydrologic Management; Infrastructural Policies; Irrigation; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Nutrient & Contaminant Processing; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Primary Production; Sediment; Storms & Hurricanes; Stormwater Management; Substrate; Supporting Services; Surface & Groundwater Flow; Toxics; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Water; Waterborne Discharges
Transportation Policy: Dust Control Application This action is taken to control dust from unpaved roads and other surfaces, which is generated by traffic and/or wind. Some dust control products (palliatives) for application include: water, hydroscopic palliatives, adhesive, petroleum emulsion, polymer emulsion, clay additive, and bituminous. There are specific considerations for application of each, including seasons and when to use which. For example, hygroscopic palliatives (control dust by absorbing water from the air) shall not be used in arid and semi-arid environments. Calcium chloride and magnesium chloride shall not be used in locations where the daily summertime relative humidity averages below 30%. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture; Construction Codes & Projects; Discharge Limitations; Discharges; Food & Raw Materials; Forestry; Impervious Surfaces; Infrastructural Policies; Land & Air Transportation; Mining; Non-point Source Controls; Non-point Source Runoff; Sediment; Transportation; Transportation Policies
Water Quality Management: Treating Effluent Water Through Wetlands Additional treatment of sewage is often a necessary management option because secondary treatment alone leaves 20,000 times more nutrients in the water than the safe limit for corals. High concentrations of nutrients in the water leads to eutrophication, and coral reefs are more sensitive to nutrient enrichment than any other coastal system. Wetlands are extremely successful at reducing nitrogen levels in water. Using natural wetlands or "living machines" to perform this task can actually be more cost effective than further sewage treatment. Each successive wetland treatment cell of the series can provide incredible levels of denitrification, and thus protect corals from nutrient enrichment. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. 2003. Waste Treatment Lagoon. CODE 359. U.S. Depatrment of Agriculture.

Building & Home Construction; Chemical Variables; City Planning; Civil Engineering & Construction; Coastal Development; Coastal Engineering; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Mangroves; Nutrient & Contaminant Processing; Nutrients; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Primary Production; Security & Public Administration Policies; Sewage Treatment; Supporting Services; Surface & Groundwater Flow; Toxics; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Waterborne Discharges; Wetlands
Waterway Management: Aquatic Organism Passage This management action allows for upstream and downstream passage for fish and other aquatic organisms. The passage of these organisms is often restricted by barriers which must be modified, removed, or worked around with fishways. Sites should be evaluated for variations in discharge, tidal influence, hydraulics, geomorphic impacts, sediment transport and continuity, and organic debris movement. Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Biological Monitoring & Restoration; Civil Engineering & Construction; Dam Construction & Maintenance; Ecosystem Monitoring & Restoration; Landscape Changes; Landuse Management; Water Resources
Waterway Management: Boat Access Plan An optimal boat access strategy involves conducting a survey of all public and private boat access points throughout the area. Once entry and exit sites are identified, channel markings can be placed accordingly. An effective strategy must also consider boat access needs, location, and intensity of use. This will help to efficiently mark the waterways so that there can be a reduction in damage to reefs, seagrasses and wetlands. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Anchoring & Vessel Grounding; Artisanal Fishing; Boat Movement; Boating Activities; Boating Regulations; Commercial Fisheries; Contact Uses; Cultural Policies; Culture; Decision Support; Dive, Snorkeling, & Swimming Tourism; Dredging, Draining, & Filling; Landscape Changes; Physical Damage; Public Administration; Recreational Fishing; Resource Use Management; Security; Security & Public Administration Policies; Tourism & Recreation; Tourism & Recreation Policies; Trampling; Transportation; Trawling & Fishing Gear Damage; Water; Water Resources; Water Transportation
Waterway Management: Stream Bank Riparian Plantings Planting native vegetation and trees in riparian zones helps to reduce erosion within channels. Such vegetation helps anchor the soil and sediment in place. Planting in riparian zones goes in hand with Remove Previous Canal and Irrigation Infrastructure (#274). This management option can be exercised in streams, canals used for boat passage, stormwater drainage ditches, or in agricultural irrigation channels. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Boat Movement; Boating Activities; Carbon Storage & Cycling; City Planning; Civil Engineering & Construction; Coastal Development; Construction Codes & Projects; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Food & Energy Policies; Forestry; Hydrologic Management; Infrastructural Policies; Infrastructure; Irrigation; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Nutrient & Contaminant Processing; Primary Production; Provisioning Services; Sediment; Stormwater Management; Supporting Services; Surface & Groundwater Flow; Transportation; Utilities; Water; Water Resources; Water Transportation; Waterborne Discharges
Waterway Management: Remove Previous Canal and Irrigation Infrastructure Canal and irrigation infrastructure typically includes concrete structures to control the flow of water. These low head dams, bulkheads, concrete footers, and other structures act as constricting forces in channels. This constriction leads to debris becoming lodged and thus changing the erosive forces. In turn, banks become destabilized. Channel erosion then increases along with bed scour and sediment transport. Removing these structures and making banks more gradual has the added benefit of allowing for riparian vegetation to be planted, which acts as a natural buffer. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Agriculture; Agriculture, Aquaculture, & Forestry Policies; Boat Movement; Boating Activities; City Planning; Civil Engineering & Construction; Coastal Engineering; Construction Codes & Projects; Dam Construction & Maintenance; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Food & Raw Materials; Hydrologic Management; Impervious Surfaces; Infrastructural Policies; Irrigation; Land-Based Civil Engineering; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Non-point Source Controls; Physical Damage; Sediment; Shoreline Protection; Small Boats; Substrate; Surface & Groundwater Flow; Transportation; Water; Water Resources; Water Transportation; Waterborne Discharges
Waterway Management: Manage Canal Water Quality This management option addresses water quality issues that may arise from nearshore, confined areas, specifically dead-end canals. This management response does not focus on wastewater discharges into canals, but instead on the hydrologic structure and orientation of the canal itself. Physical problems with canal orientation can lead to such problems as low flushing and build-up of weed wrack. This is a problem because the build-up of weed wrack consumes oxygen and releases nutrients as it decays. When combined with low flushing and circulation, dead end canals have decreased oxygen concentrations, accelerated eutrophication, and accumulate organic materials, pollutants and sediment. To improve the current canal system, management can inventory and map canals to identify high risk hotspots and candidates for future canal restoration projects. Canals are typically constructed to best suit the water access needs of local homes and businesses. Preventing high risk canals from being constructed, or placing certain requirements on their construction through permitting is one way to reduce future problem spots. Some design strategies include: Construct non-linear canals without right-angles and flared inlets oriented to prevailing winds. Instead of dead-ends, canals should include a flow through water exchange system or install mechanical pumps. Canals should be as wide as possible in relation to depth and length. Canal depth should be uniform or progressively shallower away from the parent waterbody, with sloping banks (eliminate requirements for navigable depths to shoreline). Some canal improvement strategies include: Implement weed gates, air curtains, and aeration systems. Direct all stormwater and effluent away from canal systems. Reduce bulkheading and restore native vegetative buffers (#1). Promote diversity of substrates and habitats. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Applied Chemicals; Biological Monitoring & Restoration; Boat Movement; Boating Activities; Building & Home Construction; Chemical Variables; City Planning; Civil Engineering & Construction; Coastal Development; Coastal Engineering; Construction Codes & Projects; Decision Support; Deforestation & Devegetation; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Docks & Marinas; Ecosystem Monitoring & Restoration; Environmental Monitoring & Restoration; Fishing Sector; Food & Energy Policies; Hydrologic Management; Improved Technology; Infrastructural Policies; Infrastructure; Land-Based Civil Engineering; Landscape Changes; Landscaping & Household Services; Landuse Management; Non-point Source Controls; Non-point Source Runoff; Nutrient & Contaminant Processing; Physical & Chemical Water Quality Criteria; Physical Damage; Physical Variables; Point & Mobile Source Controls; Point Source Discharges; Ports & Harbors; Provisioning Services; Regulating Services; Seawater Flow; Shoreline Armoring; Shoreline Protection; Small Boats; Surface & Groundwater Flow; Tourism & Recreation; Transportation; Transportation Policies; Utilities; Utility Policies; Waste Management; Waste Management Policies; Wastewater Discharge; Water; Water Depth & Sea Level; Water Resources; Water Transportation; Waterborne Discharges; Wetland & Reef Restoration; Wetlands
Waterway Management: Lagoon Restoration Many times lagoons/wetlands are filled for urban development, agricultural development, etc. Lagoons/wetlands are a sink for nutrients, sediment, and contaminants. Wetlands close to reef watersheds can be huge contributors to reef health. This is because wetlands intercept surface-water runoff from higher, drier land and retain excess nutrients and pollutants. Also, lagoons are beneficial because they provide habitat for an array of wildlife. Overall, they can greatly reduce the amount nutrient-contaminated water that reaches corals. Center for Watershed Protection. 2008. Guanica Bay watershed management plan.

Natural Resources Conservation Service. 2011. National Handbook of Conservation Practices. U.S. Department of Agriculture.

Natural Resources Conservation Service. 2008. Chapter 13, Part 650. Wetland Restoration, Enhancement or Creation. Engineering Field Handbook. U.S. Depatrment of Agriculture.

Agriculture, Aquaculture, & Forestry Policies; Biological Monitoring & Restoration; Civil Engineering & Construction; Coastal Development; Coastal Engineering; Complex Habitat & Resources; Ecosystem Monitoring & Restoration; Infrastructural Policies; Landscape Changes; Landscape Conservation & Restoration; Landuse Management; Nutrient & Contaminant Processing; Reef Habitat; Reef Inhabitants; Reef Life; Supporting Services; Wetland & Reef Restoration; Wetlands
Waterway Management: Collaborate with Projects Changing Water-Flow Other organizations may be performing restorative freshwater projects (Everglades Restoration) or other flow altering projects (e.g. canals for small boats, agricultural irrigation etc) that affect the downstream marine management area (Florida Bay). Projects on the coast that involve hydrologic modifications (such as changing salinity) must be closely monitored in order to protect reef quality. Reefs are very sensitive systems and can only survive in a narrow salinity range. By taking an active role and monitoring freshwater flow projects, management staff can better ensure proper consideration of the impact on coastal marine environments. NOAA Marine Sanctuary Program. 2007. Florida Keys National Marine Sanctuary revised management plan. National Ocean Service, Key West, FL.

Comprehensive Everglades Restoration Plan. 2010. Comprehensive Everglades Restoration Plan: 2009 System Status Report.

Collaboration & Partnering; Dam Construction & Maintenance; Decision Support; Discharge Limitations; Discharges; Ditching & Soil Disturbance; Ecosystem Monitoring & Restoration; Hydrologic Management; Landscape Changes; Point Source Discharges; Public Administration; Salinity; Security & Public Administration Policies; Surface & Groundwater Flow; Water Transportation; Waterborne Discharges

Laws

Legal Citation Purpose of Law Management Organization Database Topics
American Antiquities Act of 1906, 16 United States Code §§ 431-433. The Act provides penalties for unauthorized collection, excavation, or destruction of historic or prehistoric ruins, monuments, or objects of antiquity on lands owned or controlled by the United States. It authorized that areas of extrodinary geographical, historical , aesthetic value can be designated national monuments.

Application to Coral Reefs:Has been used by Presidential Proclamation in 2001 to expand or create two national monuments; the Virgin Islands Coral Reef Monument and the Buck Island Reef National Monument. The monuments include coral reefs.

Legislative Actions:

Comments: 		National Park Service

Jurisdiction:
United States 		City Planning; Coastal Development; Coastal Engineering; Construction Codes & Projects; Coral; Docks & Marinas; Landscape Conservation & Restoration; Marine Protected Areas; Oil & Gas Research & Exploration; Ports & Harbors; Resource Use Management
Archaeological Resources Protection Act of 1979 as amended, 16 United States Code § 470. To protect historic ruins, monuments, and objects of antiquity. Strenghtens and expands the protective provisions of the Antiquities Act of 1906 regarding archeological resources. It also revised the permitting process for conducting archeological research.

Application to Coral Reefs:

Legislative Actions:

Comments: 		National Park Service

Jurisdiction:
United States; US Territorial Waters; US Territories; Designated Marine Areas; US Virgin Islands 		Biological Monitoring & Restoration; Coastal Development; Cultural Policies; Ecosystem Monitoring & Restoration; Educational & Research Opportunities; Existence Value & Sense of Place; Public Administration; Recreational Opportunities; Resource Use Management; Responses; Special Use Permitting; Tourism & Recreation Policies
Biscayne Bay Aquatic Preserve, 18-18 Florida Administrative Code. 18-18.001 Intent. (1) The Biscayne Bay Aquatic Preserve, the boundaries of which are fully described in Rule 18-18.002, F.A.C., was established for the purpose of preserving and enhancing Biscayne Bay and all natural waterways tidally connected to the bay in an essentially natural condition so that its biological and aesthetic values may endure for the enjoyment of future generations. (2) These rules shall apply to all lands public and private within the boundaries of the preserve. However, privately owned uplands shall be excluded from these rules except as otherwise provided for herein. (3) In promulgating and implementing these rules, it is the intent of the Department to construe the provisions of Sections 258.397 and 258.35 through 258.46, F.S., together and to apply the more stringent statutory provisions for the maintenance of the preserve. (4) The preserve shall be administered and managed in accordance with the following goals: (a) To preserve, protect, and enhance Biscayne Bay and all natural waterways tidally connected to the bay by reasonable regulation of human activity within the preserve through the development and implementation of a comprehensive management program; (b) To protect and enhance the waters of the preserve so that the public may continue to enjoy the traditional recreational uses of those waters such as swimming, boating and fishing; (c) To coordinate with federal, state, and local agencies to aid in carrying out the intent of the legislature in creating the preserve; (d) To use applicable federa