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(Top) 1 Appearance 1.1 Hydrology 2 Flora 2.1 Biodiversity 2.2 Adaptations 2.3 Ecosystem services 3 Human use 3.1 Conservation 3.2 Threats 4 Freshwater swamp forest ecoregions 4.1 Afrotropic 4.2 Australasia 4.3 South and SE Asia 4.4 Neotropic 5 See also 6 References

Freshwater swamp forest

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Flooded forest

Freshwater swamp forests, or flooded forests, are forests which are inundated with freshwater, either permanently or seasonally. They normally occur along the lower reaches of rivers and around freshwater lakes. Freshwater swamp forests are found in a range of climate zones, from boreal through temperate^[1] and subtropicaltotropical.^[2]

Appearance[edit]

A freshwater swamp forest is a type of wetland ecosystem characterized by its unique hydrology and vegetation. These forests are typically found in low-lying areas, riverbanks, and floodplains where there is a consistent supply of freshwater.^[3] A forest that is frequently flooded with relatively fresh water rich in minerals is referred to as a freshwater swamp forest. Since tropical freshwater swamp forests are a subset of tropical rainforests, they share a number of environmental traits with other tropical rainforest formations.^[4]

Beyond these shared characteristics, however, the environment in freshwater swamp forests and other tropical rain forest formations can vary greatly. In inland, freshwater swamp forests, flooding is typically sporadic, irregular, or seasonal. The depth of the water also varies greatly, from a few centimeters to several meters. These physical factors affect the ecology of freshwater swamp forests, either singly or in combination.^[5]

Rain, rivers, and groundwater are all sources of water for freshwater swamp forests, whereas rain is the only source of water for peat swamp forests.^[6] The hue of the water in the freshwater swamp forest is typically an indication of the quantities of plant materials present in the water and soil.^[7] Contrary to ombrotrophic swamp forests, which only absorb nutrients from rain, freshwater swamp forest soils are relatively nutrient-rich.^[8] In freshwater swamp forests, rain and changes in the water table result in the following deposition of nutrients and alluvial soils. Due to the nutrient-rich soils of freshwater swamp forests, wetland rice farming and oil palm plantations have become very prevalent in agriculture.^[9]

Hydrology[edit]

Within aquatic ecosystems, geomorphological, biological, and biogeomorphological processes and functions are significantly influenced by the flow of water.^[10]^[11] Flow significantly affects the geomorphology, affecting the spatial and temporal benthic community structure.^[12]^[13] Freshwater swamp forests are permanently or seasonally inundated by freshwater, with water levels that fluctuate throughout the year. They are often associated with slow-moving or meandering rivers, oxbow lakes, and other water bodies.^[14] Macroinvertebrate assemblages were significantly influenced by hydrological connectivity, with highly connected water bodies exhibiting more macroinvertebrate diversity than isolated water bodies, which tended to have less diverse assemblages and were predominated by a small number of taxa. Similar impacts have been seen in tropical ecosystems where flooding during the wet or monsoon season has led to an increase in migratory species proportions and changes in community assemblages.^[15] On a smaller scale, modifications to the flow regime that result in changes to the physical environment can boost habitat variety and, as a result, boost species diversity. Additionally, a highly varied environment might provide as a haven for species during times of stress like flooding or drought.^[16] Freshwater swamp forests contain soft, unstable, and anoxic soil due to their waterlogged condition, which may have influenced the evolution of unique root adaptations in these trees that resemble those seen in a real mangrove forest.^[17]^[18]

Flora[edit]

The vegetation in freshwater swamp forests is adapted to survive in waterlogged conditions. Common tree species include various types of mangroves, palms, and hardwood trees like mahogany and ebony. The tree canopy tends to be dense and can create a shaded environment beneath.^[19]

Biodiversity[edit]

Freshwater swamp forests are rich in biodiversity and provide habitat for a wide range of plant and animal species. They support numerous aquatic species, amphibians, reptiles, and mammals. Birds are also abundant in these ecosystems. The flooded conditions can make these areas particularly important for fish breeding and spawning.^[20] Fires of various intensities were used in southern Sumatra to burn down the swamp forest to make way for agriculture. There, a rich and complex environment was reduced to a habitat made up of uniform stands of fire-resistant Melaleuca L. species thickets as a result of widespread and frequent fires.^[21] Furthermore, improper management of these ecosystems through massive logging and agricultural conversion has resulted in serious deterioration and loss of ecological and biological diversity.^[22]

Adaptations[edit]

Many plants in freshwater swamp forests have special adaptations to cope with waterlogged soils, such as pneumatophores (aerial roots) in mangroves for oxygen exchange.^[23]^[24] Some animals have adapted to life in these wet environments, like amphibians with permeable skin that can absorb oxygen from water.^[25]

Ecosystem services[edit]

Freshwater swamp forests offer a variety of ecosystem services. They act as natural buffers against flooding by absorbing excess water during heavy rains. They also filter water, helping to improve water quality by trapping sediments and pollutants.^[26] These forests are crucial for carbon sequestration, playing a role in mitigating climate change.^[27]^[28]

Human use[edit]

Local communities often rely on freshwater swamp forests for resources such as timber, non-timber forest products (e.g., fruits, honey), and fish. Traditional agriculture may take place in the drier, elevated areas around the swamp forest. However, unsustainable logging and land conversion can threaten these ecosystems.^[29]

Conservation[edit]

Freshwater swamp forests are globally important and often designated as protected areas or Ramsar wetlands due to their ecological significance. Conservation efforts aim to protect these ecosystems from degradation and promote sustainable land use practices.^[30]^[31]

Threats[edit]

Freshwater swamp forests are vulnerable to habitat destruction and degradation due to urbanization, agriculture, logging, and drainage for development. Climate change, including rising sea levels, can further threaten these ecosystems by altering water levels and salinity.^[32]

Freshwater swamp forest ecoregions[edit]

Globally, freshwater swamp forests are found in Southeast Asia, tropical Africa, and South America, with the largest areas being part of the Amazon basin. In Southeast Asia, they are found all over the region, frequently close to major rivers like the Mekong, Chao Phraya, and IrrawaddyinThailand and Myanmar, as well as numerous smaller systems like the Sedili rivers in Johor.^[33] Although freshwater swamp forests are frequently found in wet climates, they can also be found in areas that are seasonally drier, such as west New Guinea and east Java.^[34]

Freshwater swamp forests are a relatively understudied forest type in Southeast Asia, primarily because they are difficult to access and can harbor diseases spread by insects, such as mosquitoes.^[35] In the Amazon BasinofBrazil, a seasonally flooded forest is known as a várzea, and refers to a whitewater-inundated forest. Igapó refers to blackwater-inundated forest.^[36]^[37] Mangrove and peat swamp forests, for example, have a tendency to draw more attention than other wetland habitats.^[38] Peat swamp forests are swamp forests where waterlogged soils prevent woody debris from fully decomposing, which over time creates a thick layer of acidic peat.^[39]

References[edit]

^ "NatureServe Explorer 2.0".

^ "NatureServe Explorer 2.0".

^ Martin-Smith, K. M. (2004-01-01), "ECOLOGY | Aquatic Habitats in Forest Ecosystems", in Burley, Jeffery (ed.), Encyclopedia of Forest Sciences, Oxford: Elsevier, pp. 96–102, doi:10.1016/b0-12-145160-7/00024-7, ISBN 978-0-12-145160-8, retrieved 2023-10-04

^ Clews, E., Corlett, R. T., Ho, J. K. I., Koh, C. Y., Liong, S. Y., Memory, A., ... & Yeo, D. C. J. (2018). The biological, ecological and conservation significance of freshwater swamp forest in Singapore. Gard. Bull. Singapore, 70(Suppl 1), 9-31.

^ Poff, N.L., Allan, J.D., Bain, M.B., Karr, J.R., Prestegaard, K.L., Richter, B.D., Sparks, R.E. & Stromberg, J.C. (1997). The natural flow regime. BioScience 47(11): 769–784.

^ Bunn, S.E. & Arthington, A.H. (2002). Basic principles and ecological consequences of altered flow regimes for aquatic biodiversity. Environ. Manage. 30(4): 492–507.

^ Poff, N.L. & Allan, J.D. (1995). Functional organization of stream fish assemblages in relation to hydrological variability. Ecology 76(2): 606–627.

^ Bunn, S.E. & Arthington, A.H. (2002). Basic principles and ecological consequences of altered flow regimes for aquatic biodiversity. Environ. Manage. 30(4): 492–507.

^ Giesen, Wim (2018), Finlayson, C. Max; Milton, G. Randy; Prentice, R. Crawford; Davidson, Nick C. (eds.), "Tropical Freshwater Swamps (Mineral Soils)", The Wetland Book: II: Distribution, Description, and Conservation, Dordrecht: Springer Netherlands, pp. 199–226, doi:10.1007/978-94-007-4001-3_4, ISBN 978-94-007-4001-3, retrieved 2023-10-04

^ Clews, E., R. T. Corlett, J. K. I. Ho, C. Y. Koh, S. Y. Liong, A. Memory, S. J. Ramchunder et al. "The biological, ecological and conservation significance of freshwater swamp forest in Singapore." Gard. Bull. Singapore 70, no. Suppl 1 (2018): 9-31.

^ Corlett, R.T. (1986). The mangrove understory - some additional observations. J. Trop. Ecol. 20(1): 93–94.

^ Duke, Norman C.; Schmitt, Klaus (2014), Köhl, Michael; Pancel, Laslo (eds.), "Mangroves: Unusual Forests at the Seas Edge", Tropical Forestry Handbook, Berlin, Heidelberg: Springer, pp. 1–24, doi:10.1007/978-3-642-41554-8_129-1, ISBN 978-3-642-41554-8, retrieved 2023-10-04

^ "Mangroves trees and shrubs". www.fao.org. Retrieved 2023-10-04.

^ "Trees of the Mangroves". Trees of the Mangroves. Retrieved 2023-10-04.

^ Thorson, Thomas B. (January 1955). "The Relationship of Water Economy to Terrestrialism in Amphibians". Ecology. 36 (1): 100–116. Bibcode:1955Ecol...36..100T. doi:10.2307/1931435. JSTOR 1931435.

^ Steven, Diane De; Lowrance, Richard (April 2011). "Agricultural conservation practices and wetland ecosystem services in the wetland-rich Piedmont-Coastal Plain region". Ecological Applications. 21 (sp1): S3–S17. doi:10.1890/09-0231.1. ISSN 1051-0761.

^ Hawes, E., & Smith, M. (2005). Riparian buffer zones: Functions and recommended widths. Eightmile River Wild and Scenic Study Committee, 15, 2005.

^ Derebe, Binega; Alemu, Asmamaw; Asfaw, Zebene (2023-05-20). "Contribution of Nontimber Forest Products Earn to Livelihood in Rural Households and the Type of Use: A Systematic Review". International Journal of Forestry Research. 2023: e9643290. doi:10.1155/2023/9643290. ISSN 1687-9368.

^ Schlesinger, William H.; Bernhardt, Emily S. (2020-01-01), Schlesinger, William H.; Bernhardt, Emily S. (eds.), "Chapter 7 - Wetland Ecosystems", Biogeochemistry (Fourth Edition), Academic Press, pp. 249–291, doi:10.1016/b978-0-12-814608-8.00007-4, ISBN 978-0-12-814608-8, S2CID 241274254, retrieved 2023-10-05

^ "Ecology of Wetland Ecosystems: Water, Substrate, and Life | Learn Science at Scitable". www.nature.com. Retrieved 2023-10-05.

^ Verhoeven, Jos T. A.; Setter, Tim L. (2009-08-21). "Agricultural use of wetlands: opportunities and limitations". Annals of Botany. 105 (1): 155–163. doi:10.1093/aob/mcp172. ISSN 1095-8290. PMC 2794053. PMID 19700447.

^ Pinedo-Vasquez, Miguel; Ruffino, Mauro L; Padoch, Christine; Brondízio, Eduardo S, eds. (2011). The Amazon Várzea. doi:10.1007/978-94-007-0146-5. ISBN 978-94-007-0145-8.