Florida Bay

Last updated
Southern third of Florida, showing Florida Bay in pale green off the southern tip of the mainland Evergladesareamap.png
Southern third of Florida, showing Florida Bay in pale green off the southern tip of the mainland

Florida Bay is the bay located between the southern end of the Florida mainland (the Florida Everglades) and the Florida Keys in the United States. It is a large, shallow estuary that while connected to the Gulf of Mexico, has limited exchange of water due to shallow mudbanks dividing the bay into many basins or lakes. The banks separate the bay into basins, each with its own unique physical characteristics.

Contents

Description

Chart of Florida Bay showing water depths and the shoals and islands that divide it into basins or lakes FloridaBaychart.png
Chart of Florida Bay showing water depths and the shoals and islands that divide it into basins or lakes

Encompassing roughly one-third of Everglades National Park, [1] Florida Bay is variously stated to be 800 square miles (2,100 km2), [2] or 850 square miles (2,200 km2), [3] or 1,000 square miles (2,600 km2). [4] The bay has been described as an inner continental shelf lagoon. The northern edge of the bay is formed by the Florida mainland. The eastern and southern edge of the bay is defined by the Florida Keys, with only a few natural passages between islands connecting to the Atlantic Ocean. The western edge of the bay is defined by the westernmost mud banks of the bay. [5] Nearly all of Florida Bay is included in Everglades National Park. The southern edge, along the Florida Keys, is in the Florida Keys National Marine Sanctuary.

While there is no sharp boundary between Florida Bay and the Gulf of Mexico, the westernmost edge of Florida Bay can be approximated by a line drawn from Long Key to Cape Sable on the mainland, which is very close to the boundary line of Everglades National Park. [6] [7] The northeastern edge of Florida Bay is at Jewfish Creek in Key Largo. Blackwater Sound, southwest of Jewfish Creek, is generally considered part of Florida Bay; Barnes Sound, on the other side of jewfish Creek, is not. Barnes Sound is generally considered part of the Biscayne Bay system. [8]

(Looking northeast) Jewfish Creek Bridge at the northeastern end of Florida Bay. Blackwater Sound is in the foreground, and Barnes Sound (not part of Florida Bay) is in the background; Jewfish Creek connects the two. JewfishCreek-p.jpg
(Looking northeast) Jewfish Creek Bridge at the northeastern end of Florida Bay. Blackwater Sound is in the foreground, and Barnes Sound (not part of Florida Bay) is in the background; Jewfish Creek connects the two.

The bay consists of more than 50 shallow (one to three meters deep) basins or lakes separated by mud banks and mangrove islands. Such basins include: Little Blackwater Sound, Blackwater Sound, Tarpon Basin, Buttonwood Sound, Duck Key Basin, Eagle Key Basin, Madeira Bay, Calusa Key Basin, Crane Key Basin, Rankin Lake, Whipray Basin, Twin Key Basin, Rabbit Key Basin, and Johnson Key Basin. [9] [10] [11]

Water flows between the basins in narrow channels and over the mud banks. The bay is open to the Gulf of Mexico to the west, but connection to the Atlantic Ocean to the east is restricted to narrow channels between the Florida Keys. The average tidal range along the western edge of the bay is 1 to 1.5 meters, but the tidal range diminishes quickly eastward in the bay due to the restricted flow of water between basins. Fresh water flow into the bay is restricted to Taylor Slough and Trout Creek in the northeast corner of the bay, and is only 10% of the freshwater supply to the bay (rainfall provides the rest of the fresh water). Due to the poor circulation of water within the bay, salinity increases rapidly away from the margins of the bay, except for the northeast part of the bay where it receives fresh water from rivers. [12]

Temperature

Water temperature ranges from 15 to 40 °C (59 to 104 °F) in interior bays. Cold fronts cross the bay 30 to 40 times each year between November and April, rarely lowering the temperature in parts of the bay to below 13 °C (55 °F). [13]

Tides

Tides in Florida Bay are semi-diurnal, with a range of 60 centimetres (24 in) on the Atlantic side of connecting creeks in the Florida Keys and at Cape Sable. Tidal ranges are less than 15 centimetres (5.9 in) behind the first line of mud banks and absent in the northeast corner of the bay. [13]

Salinity

Due to the poor circulation of water within the bay, salinity increases rapidly away from the margins of the bay, except for the northeast part of the bay where it receives fresh water from rivers. [14] Salinity is 30% to 40% near the open waters of the continental shelf, while salinity levels range from 4% to 70% in the northeast corner of the bay. [13]

Examination of the paleontology of biota in cores from bay muds in Florida Bay have found that historically the salinity of water in Florida Bay has been primarily dependent on rainfall rather than flow from the Everglades. [15]

Salinity partially controls the occurrence of biota in the bay. The particular species of foraminifera, molluscs, algae, and seagrasses present in the waters of a locality in Florida Bay depend on the salinity. Analysis of core samples extracted from mud banks have provided a record of past salinity levels in a few parts of the bay, going back about two centuries in one case. At a site called Bob Allen in the central part of the bay, sparse seagrass cover was present from the bottom of the core, and the species present indicated a salinity in 18 to 25 parts-per-thousand (ppt) range, [a] from about 1810, until about i840. Around 1840, the foraminifera and mollusc species present changed, and vegetation almost completely disappeared from the bottom, indicating a rise in salinity to above 25 ppt. Those conditions continued until about 1910, when the pre-1840 conditions returned, with relatively dense vegetation on the bay floor. The bay floor remains covered with vegetation, but variations in the foraminifera and mollusc species present indicate rapid oscillations in salinity levels since 1940. Around 1970, changes in species and a reduction in the amount of vegetation for a few years indicated a sharp increase in salinity. [16]

A second core from Russell Bank, also in the central part of the bay, goes back to about 1876. Until about 1884, salinity at the location was greater than 25 ppt. From 1884 to about 1900 salinity was below 25 ppt, and below 18 ppt at times. From about 1900 to about 1910 salinity rose above 25 ppt. From 1910 to 1940, salinity was between 18 and 25 ppt. Salinity rose to above 25 ppt around 1940, and stayed there until about 1960, when it fell to between 15 and 25 ppt until 1980. As at the Bob Allen site, there was a brief event around 1970 that severely disrupted the presence of various species at Russell Bank. Around 1980, salinity again rose above 25 ppt. [17]

The 2015 drought period of low precipitation combined with high temperatures and calm winds that produced rapid evaporation caused salinity to increase in the semi-enclosed basins in north-central Florida Bay. Without the freshwater, the water has become stagnant and salty with excess nitrogen from the fertilizer. [18] This hyper-salinity contributes to the massive seagrass die-offs and algal blooms, and kills submerged aquatic vegetation. [19]

Geology

Florida Bay is underlain by a flat oolitic limestone bedrock, the Miami Limestone. The top of the bedrock is about 1 metre (3 ft 3 in) below sea level in the northeast corner of the bay, and slopes to 2 to 3 metres (6 ft 7 in to 9 ft 10 in) below sea level in the southwest. Isolated high spots occur at East Key, Arsnicker Key, and Lignumvitae Key, which are underlain by patches of Pleistocene coral. [20] The Miami Limestone under Florida Bay ranges in thickness from about 3 metres (9.8 ft) at Cape Sable to up to 12 metres (39 ft) along the Florida Keys, and 35 metres (115 ft) at Key West, [21] and is underlain by the Fort Thompson Formation. [22]

The Miami Limestone of Florida Bay formed during the Sangamon interglacial between the most recent glacial period, the Wisconsin, and the preceding Illinoian, centered on about 125,000 years ago. The sea level stood higher then than at present, covering much of what is now southern Florida. A coral reef grew on the eastern edge of the Florida platform, while the shallow, protected waters west of the reef formed oolites or hosted large fields of bryozoans. [23] [7]

Origin

Throughout the Wisconsin glaciation the sea level was much lower than today and the area that is now Florida Bay was dry land. As the glaciation ended with the Pleistocene period, sea level rise rapidly, only slowing down about 7,000 years ago as the sea level reached about 8 metres (26 ft) below the late 20th century level. Sea level continued to rise thereafter at an average rate of about 11 centimetres (4.3 in) per century. [24] During the last 6,000 to 7,000 years a wet climate allowed sawgrass-dominated wetlands resembling the Evereglades to develop on the land that is now under Florida Bay. Between 3,000 and 5,000 years ago, the continued rise of the sea level flooded the gently sloping southernmost part of the Everglades to form Florida Bay. [25] [26]

There are tree islands throughout the Everglades, clusters of trees growing on slight elevations. Tree islands accumulate plant litter which becomes peat, which in turn facilitates the creation of caliche, a dense limestone crust on the limestone bedrock. As the bay flooded, a layer of grey to black calcium carbonate mud, rich in hydrogen sulfide, formed on the bottom. The mud layer is thicker on islands covered by mangrovess, and in banks connecting the islands. Peat and caliche remnants from the Everglades tree islands remain under the islands and banks. [27]

Mud mounds

As the rising sea level flooded the area that is now Florida Bay between 3,000 and 5,000 years ago, peat deposits from tree islands, shore levees, and irregularities in the bedrock surface served as nuclei for mud banks. [26] The mud mounds (islands and banks) of Florida Bay, which divide the bay into many basins or lakes, are subject to various processes that degrade, move, and built the mounds. These processes are dependent on the production of carbonate, which occurs at different rates across the bay. Carbonate is produced at high enough rates in the more open (western) part of the bay for mud mounds to acquire sediment, and have grown together to form large structures, while mounds in the central part of the bay can grow only by the movement of sediment from the bottoms of basins onto the mounds. Mounds in the inner part of the bay are smaller, and grow slowly because of low production rates of carbonate. [28] The growth and development of mud banks is controlled by biological processes, including the baffling of water movement and binding of sediment by seagrasses. [26]

Mud banks in the central part of the bay tend to run in a northwest to southeast direction, corresponding to the direction of approach of cold fronts across the bay. The mud bank called Upper Cross Bank is 4 kilometres (2.5 mi) long and 400 to 700 metres (1,300 to 2,300 ft) wide. Upper Cross Bank is eroding on the windward (east) side at a rate of 20 centimetres (7.9 in) vertically and 2 to 3 metres (6 ft 7 in to 9 ft 10 in) laterally over five years, while the leeward (west) side is growing at a rate of 10 centimetres (3.9 in) vertically and 10 to 20 metres (33 to 66 ft) laterally 0ver the same five years. [29]

Mud mounds are made up of facies, thin layers of different types of rock. The lowest facies of Upper Cross Bank, 15 to 25 centimetres (5.9 to 9.8 in) thick, is a basal packstone, which is also found widely on the bottom of basins in the bay. The packstone resembles stone that commonly forms on limestone at the bottom of lakes. The presence of remnants of the algae Halimeda in the packstone may indicate that it formed when the bay was more open. Mud mounds appear to be migrating over the basal packstone in the basins. The basal packstone in the basins has also been reworked by hurricanes. [30]

Flora and fauna

The bay's many basins that are broken up by banks serve as plentiful fishing grounds for snook (Centropomus undecimalis), redfish (Sciaenops ocellatus), spotted seatrout (Cynoscion nebulosus), tarpon (Megaflops atlanticus), bonefish (Albula vulpes), and permit (Trichinous falcatus), among others. [31]

The bay is home to many species of wading birds. Most notably, Roseate spoonbills (Platalea ajaja), Reddish egrets (Egretta rufescens), and Great White Herons (Ardea herodias occidentalis) have unique subpopulations that are largely restricted to Florida Bay. [32] Other bird species include Bald eagles, seagulls, pelicans, sandpipers, cormorants, ospreys, and flamingos. [33]

Bay land animals include raccoons, opossums, bobcats, and fox squirrels. [33]

Environmental issues

Florida Bay has undergone a series of ecological changes beginning in the late 1980s that have severely altered the ecosystem. [34] Originally, clean freshwater flowed south through the state into the Florida Bay. To support the state's agricultural water needs, namely for sugar cultivation, the water was rerouted and no longer flows into the Bay. The flow of fresh water is believed to have caused environmental issues and loss of native wildlife. [35]

Seagrass die-off

Rafts of dead seagrass in Florida Bay. 2015. Rafts of dead seagrass in Florida Bay.png
Rafts of dead seagrass in Florida Bay. 2015.

The rerouting of the flow of freshwater to the Bay coupled with periods of drought have caused massive seagrass die-offs. [36] The first major die-off occurred from 1987 to 1991 as thousands of hectares of turtlegrass beds ( Thalassia testudinum ) were devastated by high levels of toxic dissolved sulfide. [37] 10,000 acres died in the central and western bay, and almost 60,000 additional acres suffered reduced productivity and biomass as a result. [19] Then, following the 2015 drought, extreme temperatures and heightened salinity reduced the amount of oxygen that could remain dissolved in the water, causing periods of anoxia during nighttime and thereby damaging the health of the turtlegrass in the bay. During the summer and fall of 2015, approximately 40,000 acres of seagrass died. [38]

Red = area containing dead turtle grass in patches of varying size; not 100% dead. Yellow = mixed live/dead impacted areas. Green = healthy turtle grass. Striped area = dense seagrass most at risk of die-off expansion. Area of Florida Bay turtle grass die-off event in July 2015 through February 2016.png
Red = area containing dead turtle grass in patches of varying size; not 100% dead. Yellow = mixed live/dead impacted areas. Green = healthy turtle grass. Striped area = dense seagrass most at risk of die-off expansion.

Algae blooms

Cyanobacterial harmful algae blooms (also known as blue-green algae) have flourished in the bay due to a variety of environmental stressors: Agricultural fertilizer run-off increases nutrients in the delicately balanced environment and the excess increases the bacteria's rate of growth; The newly hyper-saline environment provides an ideal breeding ground for cyanobacteria; [39] Rafts of dead seagrass floating on the surface of the water as well as decaying on the bay bottom leads to anoxia and in turn, algal blooms. [36]

Blue-green algae causes numerous severe health consequences for the marine ecosystem as well surrounding human populations. Blooms result in reduced dissolved oxygen concentrations, alterations in aquatic food webs, algal scum lining the shores, the production of compounds that cause distasteful drinking water and fish flesh, and the production of toxins severe enough to poison aquatic as well as terrestrial organisms. [40] Blooms have been reported throughout the continental United States, and resulting cyanotoxins have been associated with human and animal illness and death in at least 43 states. [41] Most cyanobacteria produce the neurotoxin beta-N-methylamino-l-alanine (BMAA) that has been implicated as a significant environmental risk in the development of neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease, and amyotrophic lateral sclerosis (ALS). [42] The cyanobacteria has also been linked to liver cancer, chronic fatigue illness, skin rashes, abdominal cramps, nausea, diarrhea and vomiting. [43]

The 2002 algal bloom in the central portion of the Florida Bay was associated with high concentrations of dissolved organic nitrogen and organic phosphorus, whereas the eastern bay regions bloom was associated with high concentration of inorganic nutrients. [44]

Loss of native wildlife

By the mid 1930s, the three main species of wading birds in the bay (Roseate spoonbills, Reddish egrets, Great herons) were driven to near extinction by human harvesting for food and feathers. [32]

The cyanobacteria create an oxygen-free environment teaming with toxic gases, creating an unsuitable living environment for many marine and terrestrial animal species. [45] As a result, seasons during which algal blooms flourish cause a temporary loss in wildlife.

Spotted seatrout populations in the coasted Everglades are declining. [46] As the second most commonly caught species of fish in the Florida Bay, spotted seatrout comprise a large portion of the fishing industry and are integral to the ecosystem as well as surrounding economy. Water temperature of less than 80 °F (27 °C) and salinity levels below 37.5 parts per thousand (ppt) are ideal for seatrout spawning; however, water management stations in the Everglades and Florida Bay reported salinity levels of 64.4 ppt in July 2015 and recorded water temperatures of up to 92 °F (33 °C). [46] These environmental conditions are far from ideal for the seatrout and add additional difficulties for the survival of juveniles as well as important prey such as larval shrimp and small fish. [46]

Economy

The bay is an economic and environmental asset. As of 2017, the recreational fishing industry in Florida Bay had an estimated value of $7.1 billion, and generated $73 million in federal, state and local taxes annually, while the bay's commercial fishing industry had an estimated value of $400 million, and generated $3 million in taxes. [47]

Water management projects

Various projects are funded by the government in an attempt to manage the hydrology issues present in the Florida Bay, including the C-111 South Dade, Modified Water Deliveries, and C-111 Spreader Canal Western Project from the Comprehensive Everglades Restoration Plan (CERP). [35] These projects seek to distribute more freshwater into the sloughs but do not deliver additional water to the bay.

The U.S. Atlantic Intracoastal Waterway goes through Florida Bay, generally following the southern boundary of the Everglades National Park. [10] Florida Bay is a Marine protected area designated as a "Particularly Sensitive Sea Area" by the International Maritime Organization in 2002. [48] Boating in Florida Bay off the Intracoastal Waterway is considered challenging, because of shallow depths, mud, and seagrass. [49]

Notes

  1. Ocean water is 30 to 35 ppt.

Related Research Articles

<span class="mw-page-title-main">Limestone</span> Type of sedimentary rock

Limestone is a type of carbonate sedimentary rock which is the main source of the material lime. It is composed mostly of the minerals calcite and aragonite, which are different crystal forms of CaCO3. Limestone forms when these minerals precipitate out of water containing dissolved calcium. This can take place through both biological and nonbiological processes, though biological processes, such as the accumulation of corals and shells in the sea, have likely been more important for the last 540 million years. Limestone often contains fossils which provide scientists with information on ancient environments and on the evolution of life.

<span class="mw-page-title-main">Biscayne National Park</span> American national park located south of Miami, Florida

Biscayne National Park is a national park of the United States located south of Miami, Florida, in Miami-Dade County. The park preserves Biscayne Bay and its offshore barrier reefs. Ninety-five percent of the park is water, and the shore of the bay is the location of an extensive mangrove forest. The park covers 172,971 acres and includes Elliott Key, the park's largest island and northernmost of the true Florida Keys, formed from fossilized coral reef. The islands farther north in the park are transitional islands of coral and sand. The offshore portion of the park includes the northernmost region of the Florida Reef, one of the largest coral reefs in the world.

<span class="mw-page-title-main">Everglades National Park</span> National park in Florida, United States

Everglades National Park is a national park of the United States that protects the southern twenty percent of the original Everglades in Florida. The park is the largest tropical wilderness in the United States and the largest wilderness of any kind east of the Mississippi River. An average of one million people visit the park each year. Everglades is the third-largest national park in the contiguous United States after Death Valley and Yellowstone. UNESCO declared the Everglades & Dry Tortugas Biosphere Reserve in 1976 and listed the park as a World Heritage Site in 1979, and the Ramsar Convention included the park on its list of Wetlands of International Importance in 1987. Everglades is one of only three locations in the world to appear on all three lists.

<span class="mw-page-title-main">Permian Basin (North America)</span> Large sedimentary basin in the US

The Permian Basin is a large sedimentary basin in the southwestern part of the United States. It is the highest producing oil field in the United States, producing an average of 4.2 million barrels of crude oil per day in 2019. This sedimentary basin is located in western Texas and southeastern New Mexico.

<span class="mw-page-title-main">Lake Okeechobee</span> Natural freshwater lake in Florida, United States

Lake Okeechobee is the largest freshwater lake in the U.S. state of Florida. It is the eighth-largest natural freshwater lake among the 50 states of the United States and the second-largest natural freshwater lake contained entirely within the contiguous 48 states, after Lake Michigan.

<span class="mw-page-title-main">Coquina</span> Sedimentary rock that is composed mostly of fragments of shells

Coquina is a sedimentary rock that is composed either wholly or almost entirely of the transported, abraded, and mechanically sorted fragments of mollusks, trilobites, brachiopods, or other invertebrates. The term coquina comes from the Spanish word for "cockle" and "shellfish".

<span class="mw-page-title-main">Biscayne Bay</span> Florida lagoon

Biscayne Bay is a lagoon with characteristics of an estuary located on the Atlantic coast of South Florida. The northern end of the lagoon is surrounded by the densely developed heart of the Miami metropolitan area while the southern end is largely undeveloped with a large portion of the lagoon included in Biscayne National Park.

<span class="mw-page-title-main">Algal mat</span> Microbial mat that forms on the surface of water or rocks

Algal mats are one of many types of microbial mat that forms on the surface of water or rocks. They are typically composed of blue-green cyanobacteria and sediments. Formation occurs when alternating layers of blue-green bacteria and sediments are deposited or grow in place, creating dark-laminated layers. Stromatolites are prime examples of algal mats. Algal mats played an important role in the Great Oxidation Event on Earth some 2.3 billion years ago. Algal mats can become a significant ecological problem, if the mats grow so expansive or thick as to disrupt the other underwater marine life by blocking the sunlight or producing toxic chemicals.

<span class="mw-page-title-main">Carbonate platform</span> Sedimentary body with topographic relief composed of autochthonous calcareous deposits

A carbonate platform is a sedimentary body which possesses topographic relief, and is composed of autochthonic calcareous deposits. Platform growth is mediated by sessile organisms whose skeletons build up the reef or by organisms which induce carbonate precipitation through their metabolism. Therefore, carbonate platforms can not grow up everywhere: they are not present in places where limiting factors to the life of reef-building organisms exist. Such limiting factors are, among others: light, water temperature, transparency and pH-Value. For example, carbonate sedimentation along the Atlantic South American coasts takes place everywhere but at the mouth of the Amazon River, because of the intense turbidity of the water there. Spectacular examples of present-day carbonate platforms are the Bahama Banks under which the platform is roughly 8 km thick, the Yucatan Peninsula which is up to 2 km thick, the Florida platform, the platform on which the Great Barrier Reef is growing, and the Maldive atolls. All these carbonate platforms and their associated reefs are confined to tropical latitudes. Today's reefs are built mainly by scleractinian corals, but in the distant past other organisms, like archaeocyatha or extinct cnidaria were important reef builders.

<span class="mw-page-title-main">Hamelin Pool Marine Nature Reserve</span> Protected area in Western Australia

The Hamelin Pool Marine Nature Reserve is a protected marine nature reserve located in the UNESCO World Heritage–listed Shark Bay in the Gascoyne region of Western Australia. The 127,000-hectare (310,000-acre) nature reserve boasts the most diverse and abundant examples of living marine stromatolites in the world, monuments to life on Earth over 3,500 million years BP.

<span class="mw-page-title-main">Sabkha</span> Salt lake above the tide line, where evaporite deposits accumulate

A sabkha is a coastal, supratidal mudflat or sandflat in which evaporite-saline minerals accumulate as the result of semiarid to arid climate. Sabkhas are gradational between land and intertidal zone within restricted coastal plains just above normal high-tide level. Within a sabkha, evaporite-saline minerals sediments typically accumulate below the surface of mudflats or sandflats. Evaporite-saline minerals, tidal-flood, and aeolian deposits characterize many sabkhas found along modern coastlines. The accepted type locality for a sabkha is at the southern coast of the Persian Gulf, in the United Arab Emirates. Evidence of clastic sabkhas are found in the geological record of many areas, including the UK and Ireland. Sabkha is a phonetic transliteration of the Arabic word used to describe any form of salt flat. A sabkha is also known as a sabkhah,sebkha, or coastal sabkha.

<span class="mw-page-title-main">Cyclic sediments</span>

Cyclic sediments are sequences of sedimentary rocks that are characterised by repetitive patterns of different rock types (strata) or facies within the sequence. Processes that generate sedimentary cyclicity can be either autocyclic or allocyclic, and can result in piles of sedimentary cycles hundreds or even thousands of metres thick. The study of sequence stratigraphy was developed from controversies over the causes of cyclic sedimentation.

<span class="mw-page-title-main">St. Lucie River</span> River in the United States of America

The St. Lucie River is a 35-mile-long (56 km) estuary linked to a coastal river system in St. Lucie and Martin counties in the U.S. state of Florida. The St. Lucie River and St. Lucie Estuary are an "ecological jewel" of the Treasure Coast, central to the health and well-being of the surrounding communities. The river is part of the larger Indian River Lagoon system, the most diverse estuarine environment in North America with more than 4,000 plant and animal species, including manatees, oysters, dolphins, sea turtles and seahorses.

<span class="mw-page-title-main">Harmful algal bloom</span> Population explosion of organisms that can kill marine life

A harmful algal bloom (HAB), or excessive algae growth, is an algal bloom that causes negative impacts to other organisms by production of natural algae-produced toxins, water deoxygenation, mechanical damage to other organisms, or by other means. HABs are sometimes defined as only those algal blooms that produce toxins, and sometimes as any algal bloom that can result in severely lower oxygen levels in natural waters, killing organisms in marine or fresh waters. Blooms can last from a few days to many months. After the bloom dies, the microbes that decompose the dead algae use up more of the oxygen, generating a "dead zone" which can cause fish die-offs. When these zones cover a large area for an extended period of time, neither fish nor plants are able to survive. Harmful algal blooms in marine environments are often called "red tides".

<span class="mw-page-title-main">Tin Cup Oil Field</span>

Tin Cup Oil Field is located in San Juan County, approximately 21 miles (34 km) southeast of Blanding, Utah. Production is from a northwest–southeast trending 120-foot-thick (37 m) carbonate buildup in the Pennsylvanian Upper Ismay. The field is part of the Paradox Basin that extends from the states of Colorado to Utah and New Mexico.

The Arcadia Formation is an Early Miocene geologic formation in Florida, United States. It is part of the Hawthorn Group.

<span class="mw-page-title-main">Okeechobean Sea</span>

The Okeechobean Sea was a Cenozoic eutropical subsea, which along with the Choctaw Sea, occupied the eastern Gulf of Mexico basin system bounding Florida.

<span class="mw-page-title-main">Laguna Madre (United States)</span> Hypersaline lagoon in Texas, US

The Laguna Madre is a long, shallow, hypersaline lagoon along the western coast of the Gulf of Mexico in Nueces, Kenedy, Kleberg, Willacy and Cameron Counties in Texas, United States. It is one of seven major estuaries along the Gulf Coast of Texas. The roughly 20-mile (32 km) long Saltillo Flats land bridge divides it into Upper and Lower lagoons joined by the Intracoastal Waterway, which has been dredged through the lagoon. Cumulatively, Laguna Madre is approximately 130 miles (210 km) long, the length of Padre Island in the US. The main extensions include Baffin Bay in Upper Laguna Madre, Red Fish Bay just below the Saltillo Flats, and South Bay near the Mexican border. As a natural ecological unit, the Laguna Madre of the United States is the northern half of the ecosystem as a whole, which extends into Tamaulipas, Mexico approximately 144 miles (232 km) south of the US border, to the vicinity of the Rio Soto La Marina and the town of La Pesca, extending approximately 275 miles (443 km) through USA and Mexico in total.

<span class="mw-page-title-main">Gulf flounder</span> Species of fish

The Gulf flounder is a species of saltwater flounder.

Automicrite is autochthonous micrite, that is, a carbonate mud precipitated in situ and made up of fine-grained calcite or aragonite micron-sized crystals. It precipitates on the sea floor or within the sediment as an authigenic mud thanks to physicochemical, microbial, photosynthetic and biochemical processes. It has peculiar fabrics and uniform mineralogical and chemical composition.

References

  1. Chris Mooney. "This massive seagrass die-off is the latest sign we're failing to protect the Everglades". The Washington Post. Retrieved 2016-12-13.
  2. Everglades National Park Archived 2020-11-10 at the Wayback Machine , Park Vision
  3. Florida Bay, Encyclopædia Britannica Online
  4. The Ecology of Florida Bay Archived 2020-12-13 at the Wayback Machine , by Daniel Phirman
  5. Wanless & Tagett 1989, p. 455.
  6. "Florida Bay Marine Basin Region (map)". ArcGIS Online. December 1, 2021. Retrieved May 4, 2024.
  7. 1 2 Shinn & Lidz 2018, p. 24.
  8. Smith, Ned P. (Summer 2001). "Tides of Biscayne Bay, Card Sound, Little Card Sound, Barnes Sound, and Manatee Bay, Florida". Florida Scientist. 64: 224. JSTOR   24321024.
  9. Durako, Morgan J. (2012). "Using PAM fluorometry for landscape level assessment of Thalassia testudinum:Can diurnal variation in photochemical efficiency be used as an ecoindicator of seagrass health?". Ecological Indicators. 18: 244. Bibcode:2012EcInd..18..243D. doi:10.1016/j.ecolind.2011.11.025 via ResearchGate.
  10. 1 2 OCS 1983.
  11. Shinn & Lidz 2018, pp. 21, 113.
  12. Lee, Thomas N.; Johns, Elizabeth; Smith, Ryan H.; Ortner, Peter; Smith, Dewitt (2006). "On Florida Bay Hypersalinity and Water Exchange". Bulletin of Marine Science. 79 (2): 302.
  13. 1 2 3 Wanless & Tagett 1989, p. 456.
  14. Lee, Thomas N.; Johns, Elizabeth; Smith, Ryan H.; Ortner, Peter; Smith, Dewitt (2006). "On Florida Bay Hypersalinity and Water Exchange". Bulletin of Marine Science. 79 (2): 302.
  15. "Digging Up the Past". National Park Service. Archived from the original on August 12, 2006. Retrieved August 31, 2024.
  16. Brewster-Wingard, Ishman & Holmes 1998, pp. 163–166.
  17. Brewster-Wingard, Ishman & Holmes 1998, pp. 166–167.
  18. Robert Mcclure And Don Melvin. (1993). "The Dead Zone Once A Teeming Marine Nursery, Florida Bay Today Is Dying". SunSentinel
  19. 1 2 Sklar, Fred H. (October 8, 2015). "Florida Bay: Current Conditions". South Florida Water Management District.
  20. Shinn & Lidz 2018, p. 25.
  21. Mitchell-Tapping 1980, pp. 118–119.
  22. "Fort Thompson formation, pleistocene, Florida platform". Temporal and Spatial Patterns in Carbonate Platforms. Lecture Notes in Earth Sciences. Vol. 46. Springer. 1993. p. 76. doi:10.1007/BFb0011067. ISBN   3-540-56231-1.
  23. Mitchell-Tapping 1980.
  24. Shinn & Lidz 2018, pp. 19, 23–25.
  25. Lodge 2019, 1.1 Origin and Evolution of the Everglades.
  26. 1 2 3 Wanless & Tagett 1989, p. 454.
  27. Shinn & Lidz 2018, pp. 24–25.
  28. Bosence 1995, pp. 476–478.
  29. Bosence 1995, p. 480.
  30. Bosence 1995, pp. 481–482.
  31. "Florida Bay and Everglades National Park: Flats-Fishing Paradise". Salt Water Sportsman. Retrieved 2017-06-27.
  32. 1 2 Powell, George V. N.; Bjork, Robin D.; Ogden, John C.; Paul, Richard T.; Powell, A. Harriett; Robertson, William B. (1989). "Population Trends in Some Florida Bay Wading Birds". The Wilson Bulletin. 101 (3): 436–457. JSTOR   4162751.
  33. 1 2 National Park Service. "Florida Bay Bistro" (PDF). National Park Service.
  34. Hanson, Matthew R.; Baldwin, John D. (2017-03-01). "Adjusted Diets of Bald Eagles (Haliaeetus leucocephalus) Breeding In An Altered Estuary". Journal of Raptor Research. 51 (1): 1–14. doi:10.3356/JRR-16-00005.1. ISSN   0892-1016. S2CID   89631326.
  35. 1 2 Solution 2016.
  36. 1 2 SeaGrass 2016.
  37. Yarbro, L.; Carlson, P. R. Jr. (2016-02-01). "Recurrence of Seagrass Mortality in Florida Bay: The Role of Climate Change and Implications for Carbon Sequestration". AGU Fall Meeting Abstracts. 54: EC54A–1309. Bibcode:2016AGUOSEC54A1309Y.
  38. National Park Service (May 2016). "2015 Florida Bay Seagrass Die-Off" (PDF). South Florida Natural Resources Center.
  39. "General Information| Harmful Algal Blooms | CDC". www.cdc.gov. Retrieved 2017-06-27.
  40. Jennifer L. Graham, Neil M. Dubrovsky, Sandra M. Eberts (2016). "Cyanobacterial Harmful Algal Blooms and U.S. Geological Survey Science Capabilities" (PDF). USGS. Archived from the original (PDF) on March 4, 2017. Retrieved 2017-06-27.{{cite web}}: CS1 maint: multiple names: authors list (link)
  41. Hudnell, H.K., ed., 2008, Cyanobacterial harmful algal blooms– State of the science and research needs: Advances in Experi- mental Medicine and Biology, v. 619, 950 p.
  42. Brand, Larry E.; Pablo, John; Compton, Angela; Hammerschlag, Neil; Mash, Deborah C. (2010-09-01). "Cyanobacterial blooms and the occurrence of the neurotoxin, beta-N-methylamino-l-alanine (BMAA), in South Florida aquatic food webs". Harmful Algae. 9 (6): 620–635. Bibcode:2010HAlga...9..620B. doi:10.1016/j.hal.2010.05.002. PMC   2968748 . PMID   21057660.
  43. Guest, David (November 9, 2006). "The Lake Okeechobee Pollution Crisis and the St. Lucie River and Estuary" (PDF). EarthJustice.org.
  44. Glibert, P. M.; Heil, C. A.; Hollander, D.; Revilla, M.; Hoare, A.; Alexander, J.; Murasko, S. (2004). "Evidence for dissolved organic nitrogen and phosphorus uptake during a cyanobacterial bloom in Florida Bay". Marine Ecology Progress Series. 280: 73–83. Bibcode:2004MEPS..280...73G. doi: 10.3354/meps280073 . JSTOR   24867855.
  45. David Biello, (2008). "Oceanic Dead Zones Continue to Spread". Scientific American
  46. 1 2 3 Trout 2015.
  47. Stainback, Andrew (April 17, 2017). "The Economic Significance of Florida Bay" (PDF). conference.ifas.ufl.edu. Everglades Foundation via the University of Florida’s Institute of Food and Agricultural Sciences Office of Conferences & Institutes. Archived (PDF) from the original on May 14, 2018. Retrieved November 13, 2018.
  48. International Maritime Organization, "Particularly Sensitive Sea Areas." https://www.imo.org/en/ourwork/environment/pages/pssas.aspx
  49. U.S. National Park Service. "Florida Bay, Everglades National Park." https://www.nps.gov/places/florida-bay.htm

Sources

Further reading

25°00′01″N80°44′59″W / 25.00028°N 80.74972°W / 25.00028; -80.74972

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.