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Little Salt Spring
Little Salt Spring in November 2006
Little Salt Spring is located in Florida
Little Salt Spring
Little Salt Spring is located in the United States
Little Salt Spring
LocationNorth Port, Florida, U.S.
Coordinates27°4′29″N 82°14′0″W / 27.07472°N 82.23333°W / 27.07472; -82.23333
NRHP reference No.79000692[1]
Added to NRHPJuly 10, 1979

Little Salt Spring is an archaeological and paleontological site in North Port, Florida. The site has been owned by the University of Miami since 1980[2][3] with research performed there by the university's Rosenstiel School of Marine, Atmospheric, and Earth Science.

History

[edit]

Little Salt Spring is a feature of the karst topography of Florida, specifically an example of a sinkhole. It is classified as a third magnitude spring.[4] The numerous deep vents at the bottom of the sinkhole feed oxygen-depleted groundwater into it, producing an anoxic environment below a depth of about 5 m (16.4 ft).[4] This fosters the preservation of Paleo-Indian and early Archaic artifacts and ecofacts, as well as fossil bones of the extinct megafauna once found in Florida.[5][6][7]

Little Salt Spring was considered a shallow freshwater pond, but in 1959 SCUBA divers William Royal and Eugenie Clark discovered that it was a true sinkhole extending downward over 200 ft (61 m),[4][8] similar to the cenotes of the Yucatán Peninsula (another karst region). The actual depth of the surface pond is forty feet (12.2 m) with a central shaft dropping vertically to an inverted cone with a maximum determined depth at the outer edges of 245 feet (75 m). There are ledges around the wall of the cenote at 16 and 27 meters (52 and 89 feet) below the present water level.

The water level in the spring has varied over time. Twelve to thirteen thousand years ago the ocean level was about 100 meters (more than 300 feet) lower than at present, drawing down the water table in Florida, and the water level in Little Salt Spring was 27 meters (89 feet) lower than at present. The basin around the spring and a slough extending away from it are filled with moist, soft peat.

On July 10, 1979, the site was added to the National Register of Historic Places.[2] In 2013, the University of Miami began considering selling the site to Sarasota County Government, due to funding being cut towards maintaining the site and its facilities.[9] The University of Miami retains ownership. [10]

Ancient human use

[edit]

Hundreds of burials dating from 5,200 to 6,800 years ago have been found in the slough. As has happened in other wetland burials in Florida, such as at the Windover Archaeological Site, brain matter survived in many of the skulls. In the 1970s the overturned shell of an extinct giant land tortoise was found on the 27-meter (89 ft) ledge. A wooden stake had been driven between the carapace and the plastron, and there is evidence of a fire under the tortoise. It appears that the tortoise had been cooked in its shell. The radiocarbon date for the wooden stake was 12,030 years ago; a bone from the tortoise was dated to 13,450 years ago. Large numbers of human bones have been recovered from the spring, but were not collected under controlled conditions.[11]

See also

[edit]

References

[edit]
[edit]
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Little Salt Spring

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from Grokipedia
Little Salt Spring is a prehistoric sinkhole and underwater archaeological site located in North Port, Sarasota County, Florida, approximately 10 miles from the Gulf of Mexico, serving as a natural limestone well that preserves ancient human remains and artifacts due to its anoxic depths below 16 feet.[1][2] The site, originally a freshwater cenote during Florida's drier prehistoric climate, contains evidence of human occupation spanning the Late Paleoindian and Early Archaic periods, with artifacts dating from 12,000 to 7,000 years ago, making it one of the oldest cultural sites in the United States.[3][1] Donated to the University of Miami's Rosenstiel School of Marine, Atmospheric, and Earth Science in 1982, the 112-acre Little Salt Spring Archaeological and Ecological Preserve encompasses the spring basin and a cavern at 90 feet depth, where seasonal hunter-gatherer activities are documented through well-preserved organic materials that rarely survive in terrestrial sites.[1] Notable discoveries include a 12,000-year-old sharpened wooden stake—the second-oldest dated artifact in the southeastern United States—and a range of perishable items such as wooden tools, textiles, hair, skin, and brain tissue from 9,500 to 7,000 radiocarbon years ago, alongside an Archaic period village and cemetery dating to around 8,000 years ago with evidence of burial customs.[1][2] The site's unique preservation conditions have provided critical insights into early human lifeways, environmental changes, tool manufacture, food preparation, and genetic adaptations in prehistoric Florida, linking Paleoindian and Archaic cultures to later traditions like the Glades.[3][2] Ecologically, the preserve protects rare and endangered species within an undisturbed hydric hammock habitat, underscoring its dual role in archaeological and environmental conservation.[1]

Geography and Geology

Location and Physical Features

Little Salt Spring is situated in North Port, Sarasota County, in southern Florida, United States, approximately 10 miles (16 km) inland from the Gulf of Mexico. The site occupies roughly 111 acres of preserved land managed as an underwater archaeological and ecological preserve.[4][5] The central feature is a large, hourglass-shaped sinkhole measuring about 240 feet (73 meters) in diameter at the surface, with depths reaching approximately 250 feet (76 meters) along the edges and sloping to around 200 feet (61 meters) at the center. A shallow basin transitions into a vertical cavern that narrows at a constriction averaging 45 feet (14 meters) deep, creating a natural depression perpetually filled with water. The surrounding terrain includes peat-filled sloughs and adjacent uplands, characteristic of the region's wetland and ridge systems.[4][6]

Geological Formation

Little Salt Spring is a cover-collapse karst sinkhole formed through the dissolution of soluble limestone and associated phosphatic rocks in the underlying Floridan Aquifer system, a process characteristic of Florida's karst terrain.[7] This dissolution creates subsurface voids that eventually lead to the collapse of overlying sediments, resulting in the sinkhole's distinctive structure.[8] Classified as a third-magnitude feature due to its low discharge rate of less than 10 cubic feet per second, the sinkhole exemplifies regional geological processes where groundwater circulation erodes carbonate bedrock over extended periods.[9] The sinkhole exhibits an hourglass-shaped profile, with a surface diameter of approximately 240 feet (73 meters) and a total depth of about 72 meters below mean sea level.[3] The upper basin funnels steeply at around 25 degrees to a narrow constriction roughly 25-30 meters wide at about 30 meters depth, featuring overhanging walls and ledges before expanding into a broader lower cavern.[8] This morphology stems from progressive roof collapses and cavity enlargement during the formation phase.[7] Geological evidence indicates that the sinkhole's initial formation occurred during the Pleistocene epoch, with sedimentation records beginning around 13,500 calibrated years before present at the Pleistocene-Holocene transition.[8] Ongoing subsidence has been modulated by post-glacial sea-level rise, which elevated groundwater tables and enhanced dissolution rates, as well as fluctuations in regional hydrology from surface and intermediate aquifer interactions.[10] The hourglass configuration profoundly influences sedimentation, promoting stratified deposits through episodic collapses that deliver allochthonous clastics from the rim and erosional winnowing in the constricted zones.[8] During lowstands in the early Holocene, detrital inputs dominated the upper layers, while rising water levels later shifted patterns toward finer, organic-rich accumulations in the lower basin, restricted by the morphology's limited light penetration and sediment trapping.[7]

Hydrology and Environment

Water Characteristics

Little Salt Spring is classified as a saline spring featuring brackish water with a salinity of approximately 3 parts per thousand (ppt), corresponding to total dissolved solids averaging 3,000 mg/L.[11] The spring is fed by groundwater from the Upper Floridan Aquifer, with historical discharge measurements ranging from 9 to 11 cubic feet per second (cfs) (1942-1974), classifying it as a third-magnitude spring.[12] The water column exhibits pronounced vertical stratification, with an oxic upper layer extending to about 5 meters where aerobic conditions prevail and support a pond-like ecosystem.[11] Below this depth, the environment transitions to anoxic and sulfidic conditions, creating oxygen-depleted depths that extend to the spring's bottom at around 76 meters, fostering exceptional preservation of submerged materials.[11] Paleohydrological records reveal significant Holocene shifts in the spring's water regime, transitioning from a freshwater cenote around 12,000 years before present (yr BP) to its current brackish state.[7] This evolution is evidenced by ostracod assemblages, which document an initial dominance of freshwater species followed by the appearance of brackish taxa such as Cyprideis spp. and Limnocythere floridensis in the Late Holocene, alongside stable isotope analyses of δ¹⁸O and δ¹³C from ostracod valves indicating salinity fluctuations driven by sea-level rise, groundwater dynamics, and climatic variability over the past 12,000 years.[7]

Ecological Significance

Little Salt Spring serves as a longstanding ecological oasis, functioning as a refugium for diverse organisms over more than 15,000 years due to its stable, deep groundwater inputs and protected karst environment.[13] The surrounding 111-acre site features undisturbed native hydric hammock vegetation, supporting several rare and endangered plant and animal species adapted to wetland conditions.[1] In the upper oxygenated layers of the water column, submerged aquatic vegetation thrives, forming dense mats that provide habitat for fish and macroinvertebrates. Deeper in the anoxic zone below approximately 5 meters, where oxygen-depleted groundwater dominates, unique microbial communities persist, including biofilms of cyanobacteria and other algae capable of both oxygenic and anoxygenic photosynthesis, alongside endemic aquatic invertebrates adapted to sulfidic, low-oxygen conditions.[14] These communities contribute to the spring's role as a biodiversity hotspot, with the anoxic preservation enabling long-term stability for heat-sensitive microbes amid fluctuating surface temperatures.[4] The spring's sediment cores provide a valuable paleoenvironmental record spanning the Holocene, reconstructed through analyses of pollen, diatoms, and ostracod assemblages, revealing ecosystem transitions driven by climate and sea-level changes.[15] Pollen profiles indicate a shift from freshwater marsh dominated by herbaceous plants and conifers during the early Holocene to more brackish conditions with mangrove expansion around 6,000 years ago, reflecting post-glacial warming and rising sea levels that increased salinity and groundwater influence.[16] Ostracod faunas further document hydrologic fluctuations, with species assemblages showing initial cool, freshwater lacustrine environments giving way to warmer, brackish systems as sea-level rise encroached on the coastal plain, altering recharge patterns and water chemistry.[7] Diatom records complement these findings, highlighting periodic oligotrophic conditions in the marsh phase before eutrophication linked to marine incursions. This multiproxy evidence underscores the spring's sensitivity to regional paleoclimate dynamics, offering insights into broader Florida wetland evolution. As an underwater ecological and archaeological preserve managed by the University of Miami since 1982, Little Salt Spring protects its biodiversity under state oversight, safeguarding habitats for endemic species vulnerable to regional pressures.[1] Its thermal stability from deep aquifer sources positions it as a critical refugium for heat-sensitive aquatic organisms, including microbial mats and invertebrates, in the face of intensifying climate threats like rising temperatures and altered rainfall patterns across Florida's springs.[17] As of 2025, many Florida springs are impaired by reduced flows and nutrient pollution, posing ongoing risks to sites like Little Salt Spring.[17] However, broader environmental stressors, including nutrient pollution from development and sea-level rise exacerbating salinity shifts, pose risks to the upper-layer vegetation and overall ecosystem balance, emphasizing the need for ongoing conservation to maintain its refugial value.[18]

History and Discovery

Initial Discovery

Little Salt Spring was first identified as a significant geological feature in 1959 by scuba divers Colonel William R. "Bill" Royal, a retired U.S. Air Force officer and amateur archaeologist, and Dr. Eugenie Clark, a marine biologist and director of Mote Marine Laboratory. During their exploration of sinkholes in southwest Florida, they descended into what had previously been regarded as a shallow freshwater pond, discovering its true nature as a deep karst sinkhole with exceptional depth exceeding 70 feet and remarkably clear, anoxic water that preserved submerged materials.[19][20] During these 1959 explorations, dives by Royal and other amateur enthusiasts uncovered human skeletal remains and prehistoric artifacts embedded in the anaerobic sediments at depths around 35 feet, including bones and wooden tools that hinted at ancient human activity. These findings spurred informal excavations conducted primarily by non-professional divers like Royal, who recovered additional remains and items such as sharpened stakes without systematic documentation, often sharing or displaying them to raise awareness of the site's potential.[19][20] By the 1970s, the accumulating evidence from these initial explorations elevated Little Salt Spring's profile among archaeologists and preservationists, leading to formal evaluation of its cultural and scientific value. This recognition culminated in the site's nomination and listing on the National Register of Historic Places on July 10, 1979, under reference number 79000692, affirming its status as a key underwater archaeological resource.[21]

Research and Excavations

In 1982, the University of Miami acquired Little Salt Spring through a donation from the General Development Corporation, placing it under the stewardship of the Rosenstiel School of Marine and Atmospheric Science, which has since directed formal scientific investigations at the site.[4] Systematic research resumed in earnest during the 1980s and 1990s under the leadership of archaeologist John Gifford, who conducted extensive underwater excavations to explore the sinkhole's submerged deposits.[22] These efforts employed coring techniques to extract sediment samples, including a notable 1990 campaign by Rosenstiel School scientists that recovered 35-foot (11-meter) cores from the basin floor, providing critical stratigraphic data.[4] Gifford's team also utilized underwater videography and geographical information systems (GIS) for precise documentation and mapping of excavation contexts, enabling detailed spatial analysis of the site's prehistoric layers.[23] Advancements in analytical methods have enhanced the chronological resolution of these investigations, particularly through accelerator mass spectrometry (AMS) radiocarbon dating applied to organic materials from sediment cores and artifacts, which allows for accurate layering and dating of depositional sequences spanning thousands of years.[24] This technique has been instrumental in establishing timelines for human activity and environmental changes, with multiple AMS dates from cores confirming sequences back to approximately 12,000 years before present.[7] More recent work has incorporated bioarchaeological analyses of recovered human remains, as detailed in a 2007 study by Wentz and Gifford, which examined skeletal elements to infer Middle Archaic mortuary practices, including evidence of intentional interments with grave goods and indications of biological stress such as cribra orbitalia and enamel hypoplasias.[25] Sedimentation modeling efforts, updated through 2017 research by Gregory, Reinhardt, and Gifford, have utilized core data to reconstruct paleohydrological phases influenced by the sinkhole's hourglass morphology, identifying shifts from clastic to organic-rich deposits around 8,000 calibrated years before present due to rising water levels and karst features.[26] These investigations have evolved from initial exploratory coring to integrated approaches combining geophysical sampling with advanced dating and spatial technologies, revealing the site's role as a long-term human refuge while highlighting the challenges of working in an anoxic, submerged environment.[27] For instance, analyses of faunal remains, such as tortoise shells associated with human activity layers, have been dated using AMS to contextualize prehistoric resource use without disturbing intact deposits.[22] Ongoing methodological refinements continue to prioritize non-invasive techniques to preserve the site's integrity for future study.[23]

Archaeological Findings

Prehistoric Human Use

Little Salt Spring provides significant evidence of Paleo-Indian occupation dating to approximately 12,000–13,000 years ago, representing one of the earliest known human uses of the site in prehistoric Florida. Excavations revealed a cooking site at a depth of about 26 meters, where a gopher tortoise (Gopherus polyphemus) carapace showed signs of heating, likely from boiling or roasting, associated with a fire-hardened wooden stake inserted between the carapace and plastron. Radiocarbon dating placed the tortoise bone at 13,450 ± 190 BP and the stake at 12,030 ± 200 BP, indicating intensive resource exploitation during a period of post-Pleistocene environmental transition.[3] During the Middle Archaic period, roughly 5,200–6,800 years ago, the spring functioned primarily as a mortuary pond, with evidence of intentional burials reflecting structured ritual practices. Early estimates from 1979 suggested up to 1,000 burials across the anaerobic muck layers of the basin and adjacent slough, akin to other Florida Archaic pond cemeteries like Windover, though excavations have confirmed remains representing a minimum of 44 individuals. These burials, dated to around 6,860 ± 110 years ago, suggest communal ceremonies involving water immersion, possibly tied to beliefs in aquatic afterlife transitions or seasonal gatherings.[28][3][22] The site's role as a multifaceted oasis is supported by paleoenvironmental data, including pollen analyses indicating surrounding oak-dominated savannas during periods of human occupation, which likely facilitated hunting, gathering, and resource processing. These open woodlands provided materials like oak for crafting tools and possibly natural dyes, underscoring the spring's importance as a hub for subsistence and spiritual activities in early Florida prehistory. Artifacts such as wooden throwing sticks recovered from these contexts further attest to hunting practices integrated with the site's resources.[3][29]

Artifacts and Remains

Little Salt Spring has yielded the skeletal remains of at least 44 individuals from the Middle Archaic period, representing a minimum number of individuals (MNI) based on paired femurs recovered from the submerged basin.[22] These remains, including complete crania, long bones, and soft tissues in some cases, date primarily to between 7,800 and 7,600 calendar years before present (B.P.), as determined by radiocarbon dating of brain tissue from a young female specimen, with additional dates from associated organic materials ranging from approximately 6,860 ± 110 radiocarbon years before present (rcybp).[22] Stature estimates derived from femoral measurements indicate females averaged 140–166 cm (4'7"–5'5") in height and males 154–169 cm (5'1"–5'7"), comparable to populations at the contemporaneous Windover site.[22] Evidence of trauma includes a possible traumatic amputation on a distal ulna showing extensive remodeling, while pathologies such as cribra orbitalia, periostitis, linear enamel hypoplasias in a subadult, and degenerative joint disease in vertebrae and ulnae suggest health stresses typical of hunter-gatherer lifestyles.[22] Archaeological recovery from the site includes a variety of organic artifacts dating to both Paleoindian (ca. 12,000–9,000 years ago) and Archaic (ca. 6,800–5,200 years ago) occupations, preserved in the anaerobic sediments.[30] Notable wooden implements comprise throwing sticks fashioned from oak, sharpened stakes used possibly for hunting or processing, and components of atlatls such as incised bone handles paired with wooden shafts, with one stake radiocarbon dated to approximately 12,030 years ago.[13][31] Shell tools, including blades and celts made from local marine shells, along with compound artifacts combining shell blades with bone or wooden handles, further attest to tool-making traditions, dated through association with stratified organics to 7,000–12,000 years old.[31][30] The site's anoxic, waterlogged environment at depths below 20 feet inhibits bacterial decay and scavenging, enabling the exceptional preservation of perishable materials like wood, soft tissues, and brain matter that would otherwise disintegrate in aerobic conditions.[30] Radiocarbon dating of these organics, including wooden artifacts and human tissues, confirms site use as early as 10,000 B.C., providing a rare window into perishable technologies and burial practices.[30] This preservation has allowed recovery of items integral to Archaic hunting and processing, such as the oak throwing sticks, without significant degradation.[13]

Paleontological Importance

Fossil Record

The sediment core from Little Salt Spring spans approximately 12,000 years, capturing a continuous stratigraphic record from the late Pleistocene to the present Holocene, with microfossils such as pollen, diatoms, and ostracods documenting key ecosystem transitions from open, drier habitats suitable for Pleistocene megafauna to closed, wetland-dominated environments. Pollen assemblages reveal a marked increase in pine (Pinus) pollen to 60–80% during the warmer, moister Bølling–Allerød interstadial (14,700–12,900 years ago), indicating afforestation and rising moisture levels, followed by dominance of herbaceous taxa and hickory (Carya) during the cooler Younger Dryas stadial around 12,900–11,600 years ago. By the early Holocene, stable bayhead hammock communities emerged, reflecting sustained warmer conditions, though periodic aridity episodes are evident from fluctuations in pollen diversity.[32][16][33] Invertebrate fossils, particularly well-preserved ostracod shells, serve as primary proxies for paleoclimate reconstruction, with species assemblages signaling shifts in salinity and hydrology. Cytheridella ilosvayi dominates the early Holocene record, indicating freshwater to slightly brackish conditions (<3.2 PSU) under low initial rainfall and surface runoff, transitioning around 11,000 years ago to groundwater-dominated inflow and further to deeper aquifer influence by 5,700 years ago. Later Holocene layers (2,700–900 years ago) show increased abundance of brackish species like Cyprideis spp. and Limnocythere floridensis, linked to episodic saline intrusions and higher δ¹⁸O values (up to −1.46‰), reflecting drier phases with reduced precipitation and potential sea-level influences. These changes correlate with broader regional aridity, such as during the Little Ice Age analog around 1,100–900 years ago. Ostracod δ¹³C and δ¹⁸O isotopes further confirm hydrologic variability, with low δ¹⁸O (−2.86‰) during mid-Holocene saline mixing events.[15] Plant macrofossils, including seeds and wood fragments preserved in the anoxic depths, complement pollen data by illustrating local vegetation dynamics, with evidence of cypress (Taxodium) swamps and pine dominance during drier mid-Holocene phases around 8,000–5,000 years ago. These macroremains highlight periodic expansions of coniferous woodlands amid fluctuating water tables, providing direct indicators of riparian and wetland adaptations not fully captured by pollen transport. The integrated microfossil and macrofossil record thus delineates a progression toward modern wetland ecosystems, briefly integrating with megafauna evidence in basal layers indicative of open savanna-like conditions.[30][33]

Megafauna Evidence

Remains of extinct megafauna have been recovered from the lower sediment layers of Little Salt Spring, providing key insights into the late Pleistocene fauna of southwestern Florida. Notable among these are bones of the ground sloth Megalonyx sp. and the mastodon Mammut americanum, dated to approximately 12,000 radiocarbon years before present. These specimens were preserved in anaerobic soft clay deposits on a submerged ledge approximately 26 meters below the modern water surface, where low oxygen levels and stable conditions facilitated exceptional organic preservation.[34] The megafauna fossils occur in stratigraphic association with Paleo-Indian artifacts, including a sharpened wooden stake used to dispatch a giant land tortoise (Geochelone crassiscutata), suggesting possible human interaction with local wildlife during this period. While direct evidence of hunting, such as cut marks on the megafauna bones, has not been documented, the proximity of these remains to early human tools indicates that Paleo-Indians may have encountered or exploited these large animals in the vicinity of the sinkhole. Taphonomic studies reveal that the bones exhibit minimal disturbance, consistent with natural entrapment in the karst feature rather than systematic human processing or transport.[34] This assemblage contributes significantly to paleontological understanding of megafauna extinction dynamics in Florida, where species like ground sloths and mastodons disappeared around 12,000–10,000 years ago amid climatic shifts and potential human pressures. The site's layered deposits illustrate a transition from a megafauna-rich landscape to post-extinction ecosystems, highlighting Little Salt Spring's role as a natural archive of regional biodiversity loss.[13]

Preservation and Management

Ownership and Protection

Little Salt Spring remained under private ownership until 1982, when the General Development Corporation donated the 112-acre property, including a surrounding buffer zone, to the University of Miami at the request of the Rosenstiel School of Marine, Atmospheric, and Earth Science (RSMAS) for ongoing research purposes.[35][4] The RSMAS has since managed the site as the Little Salt Spring Archaeological and Ecological Preserve, restricting public access to protect its underwater features and support scientific study.[1] In 1979, the site received federal recognition through its listing on the National Register of Historic Places under reference number 79000692, highlighting its significance as an archaeological and paleontological resource.[36] During the 1980s, following the transfer to university control, the spring was established as an underwater archaeological preserve, emphasizing the preservation of its submerged artifacts and remains under Florida's cultural resource protections.[7] Efforts to transfer ownership from the University of Miami to Sarasota County began in 2013, with the university offering to sell the property amid funding challenges for maintenance.[37] Negotiations continued through 2018 but ultimately stalled due to difficulties in securing state or federal partnerships and resolving financial terms.[38] As of November 2025, the site remains under University of Miami ownership, with no confirmed changes in control.[1]

Current Status and Threats

Little Salt Spring remains under the exclusive management of the University of Miami's Rosenstiel School of Marine, Atmospheric, and Earth Science, with public access strictly restricted to protect its archaeological and ecological integrity. Diving and tours are limited to authorized scientific research, prohibiting general recreational use to prevent disturbance of the anoxic underwater environment.[1][39] Educational outreach is facilitated through the Florida Public Archaeology Network (FPAN), which provides resources such as activity booklets for schools to teach about the site's prehistoric significance and preservation needs, fostering public awareness without on-site visitation.[13] The site faces ongoing threats from regional environmental pressures, including groundwater overuse that reduces spring flow and risks aquifer depletion, potentially compromising the water levels essential for anoxic preservation. Nutrient pollution from nearby agricultural and urban runoff could trigger algal blooms, altering water clarity and oxygen levels in the upper basin. Climate change exacerbates these issues through sea-level rise, which may increase salinity intrusion into the coastal aquifer and intensify the spring's brackish conditions, threatening biodiversity in the surrounding hydric hammock.[39][40][41] From 2020 to 2025, monitoring efforts by state agencies have focused on sedimentation buildup and potential biodiversity loss in Florida's coastal springs.[42][40] The Florida Forever program supports conservation funding for springs and cultural resources, including archaeological sites.[43]

References

  1. Little Salt Spring | Rosenstiel School
  2. Drowned Prehistoric Sites - Division of Historical Resources
  3. Little Salt Spring, Florida: A Unique Underwater Site - Science
  4. Q & A - Rosenstiel School of Marine and Atmospheric Science
  5. A Sinkhole to the Past - University of Miami News
  6. [PDF] FLORIDA'S DEEP PAST: THE ... - Rachel K. Wentz
  7. Holocene paleohydrology of Little Salt Spring, Florida, based on ...
  8. (PDF) The Influence of Morphology on Sinkhole Sedimentation at ...
  9. [PDF] Discharge, Water Temperature, and Water Quality of Warm Mineral ...
  10. https://www.sciencedirect.com/science/article/abs/pii/S003101820500013X
  11. Fact Sheet - Rosenstiel School of Marine and Atmospheric Science
  12. Little Salt Springs - The Florida Guidebook
  13. [PDF] Little Salt Spring Activity Book - Florida Public Archaeology Network
  14. (PDF) Geomicrobiology and hopanoid content of sulfidic subsurface ...
  15. Holocene paleohydrology of Little Salt Spring, Florida, based on ...
  16. Vegetation changes during the last deglacial and early Holocene
  17. Florida's 1100 natural springs are under threat - WLRN
  18. Florida's once-pristine springs threatened by pollution, development ...
  19. Remnants of Ancient Civilizations Are Still Around Us, But They're ...
  20. [PDF] Exploration of Deep Hole, Myakka River State Park, Florida
  21. Little Salt Spring - Clio
  22. (PDF) Florida's deep past: The bioarchaeology of Little Salt Spring ...
  23. Publications - Rosenstiel School of Marine and Atmospheric Science
  24. radiocarbon dates from warm mineral springs, little ... - Academia.edu
  25. florida's deep past: the bioarchaeology of little salt spring - jstor
  26. The Influence of Morphology on Sinkhole Sedimentation at Little Salt ...
  27. Little Salt Spring Archaeological Excavation - YouTube
  28. Florida's Deep Past: The Bioarchaeology of Little Salt Spring (8So18 ...
  29. [PDF] Archaic Period Archaeology of the Georgia Coastal Plain and ...
  30. Little Salt Spring, Florida: A Unique Underwater Site - jstor
  31. [PDF] Little Salt Spring: Lower Basin Artifacts from LSS
  32. Deglacial climate variability in central Florida, USA - ScienceDirect
  33. Late Wisconsin Climate of Northern Florida and the Origin of ... - jstor
  34. Fossil vertebrates associated with paleo-Indian artifact at Little Salt ...
  35. History - Rosenstiel School of Marine and Atmospheric Science
  36. [PDF] nr-archeological-resources.pdf - NPS History
  37. Little Salt Spring underwater archeological site in Florida receives ...
  38. University offers to sell Little Salt Spring - Sarasota Herald-Tribune
  39. Negotiations to begin again in effort to transfer ownership of Little ...
  40. Florida's 1100 natural springs are under threat - | The Invading Sea
  41. Climate Change Impacts on Coasts | US EPA
  42. [PDF] 2025 Florida Forever Plan
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