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Limnology

January 23, 2023

Limnology (/lɪmˈnɒləi/ lim-NOL-ə-jee; from Greek λίμνη, limne, "lake" and λόγος, logos, "knowledge") is the study of inland aquatic ecosystems.[1] The study of limnology includes aspects of the biological, chemical, physical, and geological characteristics of fresh and saline, natural and man-made bodies of water. This includes the study of lakes, reservoirs, ponds, rivers, springs, streams, wetlands, and groundwater.[2] Water systems are often categorized as either running (lotic) or standing (lentic).[3]

Lake Hawea, New Zealand

Limnology includes the study of the drainage basin, movement of water through the basin and biogeochemical changes that occur en route. A more recent sub-discipline of limnology, termed landscape limnology, studies, manages, and seeks to conserve these ecosystems using a landscape perspective, by explicitly examining connections between an aquatic ecosystem and its drainage basin. Recently, the need to understand global inland waters as part of the Earth System created a sub-discipline called global limnology.[4] This approach considers processes in inland waters on a global scale, like the role of inland aquatic ecosystems in global biogeochemical cycles.[5][6][7][8][9]

Limnology is closely related to aquatic ecology and hydrobiology, which study aquatic organisms and their interactions with the abiotic (non-living) environment. While limnology has substantial overlap with freshwater-focused disciplines (e.g., freshwater biology), it also includes the study of inland salt lakes.

History

The term limnology was coined by François-Alphonse Forel (1841–1912) who established the field with his studies of Lake Geneva. Interest in the discipline rapidly expanded, and in 1922 August Thienemann (a German zoologist) and Einar Naumann (a Swedish botanist) co-founded the International Society of Limnology (SIL, from Societas Internationalis Limnologiae). Forel's original definition of limnology, "the oceanography of lakes", was expanded to encompass the study of all inland waters,[2] and influenced Benedykt Dybowski's work on Lake Baikal.

Prominent early American limnologists included G. Evelyn Hutchinson and Ed Deevey.[10] At the University of Wisconsin-Madison, Edward A. Birge, Chancey Juday, Charles R. Goldman, and Arthur D. Hasler contributed to the development of the Center for Limnology.[11][12]

General limnology

Physical properties

Physical properties of aquatic ecosystems are determined by a combination of heat, currents, waves and other seasonal distributions of environmental conditions.[13] The morphometry of a body of water depends on the type of feature (such as a lake, river, stream, wetland, estuary etc.) and the structure of the earth surrounding the body of water. Lakes, for instance, are classified by their formation, and zones of lakes are defined by water depth.[14][15] River and stream system morphometry is driven by underlying geology of the area as well as the general velocity of the water.[13] Stream morphometry is also influenced by topography (especially slope) as well as precipitation patterns and other factors such as vegetation and land development. Connectivity between streams and lakes relates to the landscape drainage density, lake surface area and lake shape.[15]

Other types of aquatic systems which fall within the study of limnology are estuaries. Estuaries are bodies of water classified by the interaction of a river and the ocean or sea.[13] Wetlands vary in size, shape, and pattern however the most common types, marshes, bogs and swamps, often fluctuate between containing shallow, freshwater and being dry depending on the time of year.[13]

Light interactions

Light zonation is the concept of how the amount of sunlight penetration into water influences the structure of a body of water.[13] These zones define various levels of productivity within an aquatic ecosystems such as a lake. For instance, the depth of the water column which sunlight is able to penetrate and where most plant life is able to grow is known as the photic or euphotic zone. The rest of the water column which is deeper and does not receive sufficient amounts of sunlight for plant growth is known as the aphotic zone.[13]

Thermal stratification

Similar to light zonation, thermal stratification or thermal zonation is a way of grouping parts of the water body within an aquatic system based on the temperature of different lake layers. The less turbid the water, the more light is able to penetrate, and thus heat is conveyed deeper in the water.[16] Heating declines exponentially with depth in the water column, so the water will be warmest near the surface but progressively cooler as moving downwards. There are three main sections that define thermal stratification in a lake. The epilimnion is closest to the water surface and absorbs long- and shortwave radiation to warm the water surface. During cooler months, wind shear can contribute to cooling of the water surface. The thermocline is an area within the water column where water temperatures rapidly decrease.[16] The bottom layer is the hypolimnion, which tends to have the coldest water because its depth restricts sunlight from reaching it.[16] In temperate lakes, fall-season cooling of surface water results in turnover of the water column, where the thermocline is disrupted, and the lake temperature profile becomes more uniform. In cold climates, when water cools below 4oC (the temperature of maximum density) many lakes can experience an inverse thermal stratification in winter.[17] These lakes are often dimictic, with a brief spring overturn in addition to longer fall overturn. The relative thermal resistance is the energy needed to mix these strata of different temperatures.[18]

Lake Heat Budget

An annual heat budget, also shown as θa, is the total amount of heat needed to raise the water from its minimum winter temperature to its maximum summer temperature. This can be calculated by integrating the area of the lake at each depth interval (Az) multiplied by the difference between the summer (θsz) and winter (θwz) temperatures or  Azszwz)[18]

Chemical properties

The chemical composition of water in aquatic ecosystems is influenced by natural characteristics and processes including precipitation, underlying soil and bedrock in the drainage basin, erosion, evaporation, and sedimentation.[13] All bodies of water have a certain composition of both organic and inorganic elements and compounds. Biological reactions also affect the chemical properties of water. In addition to natural processes, human activities strongly influence the chemical composition of aquatic systems and their water quality.[16]

Allochthonous sources of carbon or nutrients come from outside the aquatic system (such as plant and soil material). Carbon sources from within the system, such as algae and the microbial breakdown of aquatic particulate organic carbon, are autochthonous. In aquatic food webs, the portion of biomass derived from allochthonous material is then named "allochthony".[19] In streams and small lakes, allochthonous sources of carbon are dominant while in large lakes and the ocean, autochthonous sources dominate.[20]

Oxygen and carbon dioxide

Dissolved oxygen and dissolved carbon dioxide are often discussed together due their coupled role in respiration and photosynthesis. Dissolved oxygen concentrations can be altered by physical, chemical, and biological processes and reaction. Physical processes including wind mixing can increase dissolved oxygen concentrations, particularly in surface waters of aquatic ecosystems. Because dissolved oxygen solubility is linked to water temperatures, changes in temperature affect dissolved oxygen concentrations as warmer water has a lower capacity to "hold" oxygen as colder water.[21] Biologically, both photosynthesis and aerobic respiration affect dissolved oxygen concentrations.[16] Photosynthesis by autotrophic organisms, such as phytoplankton and aquatic algae, increases dissolved oxygen concentrations while simultaneously reducing carbon dioxide concentrations, since carbon dioxide is taken up during photosynthesis.[21] All aerobic organisms in the aquatic environment take up dissolved oxygen during aerobic respiration, while carbon dioxide is released as a byproduct of this reaction. Because photosynthesis is light-limited, both photosynthesis and respiration occur during the daylight hours, while only respiration occurs during dark hours or in dark portions of an ecosystem. The balance between dissolved oxygen production and consumption is calculated as the aquatic metabolism rate.[22]

 
Lake cross-sectional diagram of the factors influencing lake metabolic rates and concentration of dissolved gases within lakes. Processes in gold text consume oxygen and produce carbon dioxide while processes in green text produce oxygen and consume carbon dioxide.

Vertical changes in the concentrations of dissolved oxygen are affected by both wind mixing of surface waters and the balance between photosynthesis and respiration of organic matter. These vertical changes, known as profiles, are based on similar principles as thermal stratification and light penetration. As light availability decreases deeper in the water column, photosynthesis rates also decrease, and less dissolved oxygen is produced. This means that dissolved oxygen concentrations generally decrease as you move deeper into the body of water because of photosynthesis is not replenishing dissolved oxygen that is being taken up through respiration.[16] During periods of thermal stratification, water density gradients prevent oxygen-rich surface waters from mixing with deeper waters. Prolonged periods of stratification can result in the depletion of bottom-water dissolved oxygen; when dissolved oxygen concentrations are below 2 milligrams per liter, waters are considered hypoxic.[21] When dissolved oxygen concentrations are approximately 0 milligrams per liter, conditions are anoxic. Both hypoxic and anoxic waters reduce available habitat for organisms that respire oxygen, and contribute to changes in other chemical reactions in the water.[21]

Nitrogen and phosphorus

Nitrogen and phosphorus are ecologically significant nutrients in aquatic systems. Nitrogen is generally present as a gas in aquatic ecosystems however most water quality studies tend to focus on nitrate, nitrite and ammonia levels.[13] Most of these dissolved nitrogen compounds follow a seasonal pattern with greater concentrations in the fall and winter months compared to the spring and summer.[13] Phosphorus has a different role in aquatic ecosystems as it is a limiting factor in the growth of phytoplankton because of generally low concentrations in the water.[13] Dissolved phosphorus is also crucial to all living things, is often very limiting to primary productivity in freshwater, and has its own distinctive ecosystem cycling.[16]

Biological properties

 
Lake George, New York, United States, an oligotrophic lake

Role in ecology

Lakes "are relatively easy to sample, because they have clear-cut boundaries (compared to terrestrial ecosystems) and because field experiments are relatively easy to perform.", which make then especially useful for ecologists who try to understand ecological dynamics.[23]

Lake trophic classification

One way to classify lakes (or other bodies of water) is with the trophic state index.[2] An oligotrophic lake is characterized by relatively low levels of primary production and low levels of nutrients. A eutrophic lake has high levels of primary productivity due to very high nutrient levels. Eutrophication of a lake can lead to algal blooms. Dystrophic lakes have high levels of humic matter and typically have yellow-brown, tea-coloured waters.[2] These categories do not have rigid specifications; the classification system can be seen as more of a spectrum encompassing the various levels of aquatic productivity.

Professional organizations

People who study limnology are called limnologists. These scientists largely study the characteristics of inland fresh-water systems such as lakes, rivers, streams, ponds and wetlands. They may also study non-oceanic bodies of salt water, such as the Great Salt Lake.There are many professional organizations related to limnology and other aspects of the aquatic science, including the Association for the Sciences of Limnology and Oceanography, the Asociación Ibérica de Limnología, the International Society of Limnology, the Polish Limnological Society, the Society of Canadian Limnologists, and the Freshwater Biological Association.

See also

  • Hydrology – Science of the movement, distribution, and quality of water on Earth and other planets
  • Lake ecosystem, also known as Lentic ecosystems – Type of ecosystem
  • Limnological tower – Structure for the study of aquatic ecosystems
  • River ecosystem, also known as Lotic ecosystems – Type of aquatic ecosystem with flowing freshwater
  • Paleolimnology – Scientific study of ancient lakes and streams

References

  1. ^ Kumar, Arvind (2005). Fundamentals of Limnology. APH Publishing. ISBN 9788176489195.
  2. ^ a b c d Wetzel, R.G. 2001. Limnology: Lake and River Ecosystems, 3rd ed. Academic Press (ISBN 0-12-744760-1)[page needed]
  3. ^ Marsh, G. Alex; Fairbridge, Rhodes W. (1999), "Lentic and lotic ecosystems", Environmental Geology, Dordrecht: Springer Netherlands, pp. 381–388, doi:10.1007/1-4020-4494-1_204, ISBN 978-1-4020-4494-6, retrieved 2022-04-21
  4. ^ Downing, John A. (January 2009). "Global limnology: up-scaling aquatic services and processes to planet Earth". SIL Proceedings, 1922-2010. 30 (8): 1149–1166. doi:10.1080/03680770.2009.11923903. S2CID 131488888.
  5. ^ Cole, J. J.; Prairie, Y. T.; Caraco, N. F.; McDowell, W. H.; Tranvik, L. J.; Striegl, R. G.; Duarte, C. M.; Kortelainen, P.; Downing, J. A.; Middelburg, J. J.; Melack, J. (23 May 2007). "Plumbing the Global Carbon Cycle: Integrating Inland Waters into the Terrestrial Carbon Budget". Ecosystems. 10 (1): 172–185. CiteSeerX 10.1.1.177.3527. doi:10.1007/s10021-006-9013-8. S2CID 1728636.
  6. ^ Tranvik, Lars J.; Downing, John A.; Cotner, James B.; Loiselle, Steven A.; Striegl, Robert G.; Ballatore, Thomas J.; Dillon, Peter; Finlay, Kerri; Fortino, Kenneth; Knoll, Lesley B.; Kortelainen, Pirkko L.; Kutser, Tiit; Larsen, Soren; Laurion, Isabelle; Leech, Dina M.; McCallister, S. Leigh; McKnight, Diane M.; Melack, John M.; Overholt, Erin; Porter, Jason A.; Prairie, Yves; Renwick, William H.; Roland, Fabio; Sherman, Bradford S.; Schindler, David W.; Sobek, Sebastian; Tremblay, Alain; Vanni, Michael J.; Verschoor, Antonie M.; von Wachenfeldt, Eddie; Weyhenmeyer, Gesa A. (November 2009). "Lakes and reservoirs as regulators of carbon cycling and climate". Limnology and Oceanography. 54 (6part2): 2298–2314. Bibcode:2009LimOc..54.2298T. doi:10.4319/lo.2009.54.6_part_2.2298. hdl:10852/11601.
  7. ^ Raymond, Peter A.; Hartmann, Jens; Lauerwald, Ronny; Sobek, Sebastian; McDonald, Cory; Hoover, Mark; Butman, David; Striegl, Robert; Mayorga, Emilio; Humborg, Christoph; Kortelainen, Pirkko; Dürr, Hans; Meybeck, Michel; Ciais, Philippe; Guth, Peter (21 November 2013). "Global carbon dioxide emissions from inland waters". Nature. 503 (7476): 355–359. Bibcode:2013Natur.503..355R. doi:10.1038/nature12760. PMID 24256802. S2CID 4460910.
  8. ^ Engel, Fabian; Farrell, Kaitlin J.; McCullough, Ian M.; Scordo, Facundo; Denfeld, Blaize A.; Dugan, Hilary A.; de Eyto, Elvira; Hanson, Paul C.; McClure, Ryan P.; Nõges, Peeter; Nõges, Tiina; Ryder, Elizabeth; Weathers, Kathleen C.; Weyhenmeyer, Gesa A. (26 March 2018). "A lake classification concept for a more accurate global estimate of the dissolved inorganic carbon export from terrestrial ecosystems to inland waters". The Science of Nature. 105 (3): 25. Bibcode:2018SciNa.105...25E. doi:10.1007/s00114-018-1547-z. PMC 5869952. PMID 29582138.
  9. ^ O'Reilly, Catherine M.; Sharma, Sapna; Gray, Derek K.; Hampton, Stephanie E.; Read, Jordan S.; Rowley, Rex J.; Schneider, Philipp; Lenters, John D.; McIntyre, Peter B.; Kraemer, Benjamin M.; Weyhenmeyer, Gesa A.; Straile, Dietmar; Dong, Bo; Adrian, Rita; Allan, Mathew G.; Anneville, Orlane; Arvola, Lauri; Austin, Jay; Bailey, John L.; Baron, Jill S.; Brookes, Justin D.; Eyto, Elvira de; Dokulil, Martin T.; Hamilton, David P.; Havens, Karl; Hetherington, Amy L.; Higgins, Scott N.; Hook, Simon; Izmest'eva, Lyubov R.; Joehnk, Klaus D.; Kangur, Kulli; Kasprzak, Peter; Kumagai, Michio; Kuusisto, Esko; Leshkevich, George; Livingstone, David M.; MacIntyre, Sally; May, Linda; Melack, John M.; Mueller‐Navarra, Doerthe C.; Naumenko, Mikhail; Noges, Peeter; Noges, Tiina; North, Ryan P.; Plisnier, Pierre-Denis; Rigosi, Anna; Rimmer, Alon; Rogora, Michela; Rudstam, Lars G.; Rusak, James A.; Salmaso, Nico; Samal, Nihar R.; Schindler, Daniel E.; Schladow, S. Geoffrey; Schmid, Martin; Schmidt, Silke R.; Silow, Eugene; Soylu, M. Evren; Teubner, Katrin; Verburg, Piet; Voutilainen, Ari; Watkinson, Andrew; Williamson, Craig E.; Zhang, Guoqing (2015). "Rapid and highly variable warming of lake surface waters around the globe". Geophysical Research Letters. 42 (24): 10, 773–10, 781. Bibcode:2015GeoRL..4210773O. doi:10.1002/2015gl066235.
  10. ^ Frey, D.G. (ed.), 1963. Limnology in North America. University of Wisconsin Press, Madison
  11. ^ "History of Limnology – UW Digital Collections". Retrieved 2019-05-02.
  12. ^ Beckel, Annamarie L. "Breaking new waters : a century of limnology at the University of Wisconsin. Special issue". {{cite journal}}: Cite journal requires |journal= (help)
  13. ^ a b c d e f g h i j Horne, Alexander J; Goldman, Charles R (1994). Limnology (Second ed.). United States of America: McGraw-Hill. ISBN 978-0-07-023673-8.[page needed]
  14. ^ Welch, P.S. (1935). Limnology (Zoological Science Publications). United States of America: McGraw-Hill. ISBN 978-0-07-069179-7.[page needed]
  15. ^ a b Seekell, D.; Cael, B.; Lindmark, E.; Byström, P. (2021). "The Fractal Scaling Relationship for River Inlets to Lakes". Geophysical Research Letters. 48 (9): e2021GL093366. Bibcode:2021GeoRL..4893366S. doi:10.1029/2021GL093366. ISSN 1944-8007. S2CID 235508504.
  16. ^ a b c d e f g Boyd, Claude E. (2015). Water Quality: An Introduction (Second ed.). Switzerland: Springer. ISBN 978-3-319-17445-7.[page needed]
  17. ^ Yang, Bernard; Wells, Mathew G.; McMeans, Bailey C.; Dugan, Hilary A.; Rusak, James A.; Weyhenmeyer, Gesa A.; Brentrup, Jennifer A.; Hrycik, Allison R.; Laas, Alo; Pilla, Rachel M.; Austin, Jay A. (2021). "A New Thermal Categorization of Ice-Covered Lakes". Geophysical Research Letters. 48 (3): e2020GL091374. Bibcode:2021GeoRL..4891374Y. doi:10.1029/2020GL091374. ISSN 1944-8007. S2CID 233921281.
  18. ^ a b Wetzel, R. G. (2001). Limnology: Lake and river ecosystems. San Diego: Academic Press.[page needed] p74, 86
  19. ^ Grosbois, G., del Giorgio, P.A. & Rautio, M. (2017). Zooplankton allochthony is spatially heterogeneous in a boreal lake. Freshwat. Biol., 62, 474-490
  20. ^ Eby, G.N., 2004, Principles of Environmental Geochemistry: Thomson Brooks/Cole, Pacific Grove, CA., 514 pp.
  21. ^ a b c d Dodds, Walter K. (2010). Freshwater ecology : concepts and environmental applications of limnology. Whiles, Matt R. (2nd ed.). Burlington, MA: Academic Press. ISBN 9780123747242. OCLC 784140625.[page needed]
  22. ^ Cole, Jonathan J.; Caraco, Nina F. (2001). "Carbon in catchments: connecting terrestrial carbon losses with aquatic metabolism". Marine and Freshwater Research. 52 (1): 101. doi:10.1071/mf00084. S2CID 11143190.
  23. ^ Lampert, W., & Sommer, U. 2007. Limnoecology.

Further reading

January 23, 2023
limnology, from, greek, λίμνη, limne, lake, λόγος, logos, knowledge, study, inland, aquatic, ecosystems, study, limnology, includes, aspects, biological, chemical, physical, geological, characteristics, fresh, saline, natural, made, bodies, water, this, includ. Limnology l ɪ m ˈ n ɒ l e dʒ i lim NOL e jee from Greek limnh limne lake and logos logos knowledge is the study of inland aquatic ecosystems 1 The study of limnology includes aspects of the biological chemical physical and geological characteristics of fresh and saline natural and man made bodies of water This includes the study of lakes reservoirs ponds rivers springs streams wetlands and groundwater 2 Water systems are often categorized as either running lotic or standing lentic 3 Lake Hawea New Zealand Limnology includes the study of the drainage basin movement of water through the basin and biogeochemical changes that occur en route A more recent sub discipline of limnology termed landscape limnology studies manages and seeks to conserve these ecosystems using a landscape perspective by explicitly examining connections between an aquatic ecosystem and its drainage basin Recently the need to understand global inland waters as part of the Earth System created a sub discipline called global limnology 4 This approach considers processes in inland waters on a global scale like the role of inland aquatic ecosystems in global biogeochemical cycles 5 6 7 8 9 Limnology is closely related to aquatic ecology and hydrobiology which study aquatic organisms and their interactions with the abiotic non living environment While limnology has substantial overlap with freshwater focused disciplines e g freshwater biology it also includes the study of inland salt lakes Contents 1 History 2 General limnology 2 1 Physical properties 2 1 1 Light interactions 2 1 2 Thermal stratification 2 1 3 Lake Heat Budget 2 2 Chemical properties 2 2 1 Oxygen and carbon dioxide 2 2 2 Nitrogen and phosphorus 2 3 Biological properties 2 3 1 Role in ecology 2 3 2 Lake trophic classification 3 Professional organizations 4 See also 5 References 6 Further readingHistory EditThe term limnology was coined by Francois Alphonse Forel 1841 1912 who established the field with his studies of Lake Geneva Interest in the discipline rapidly expanded and in 1922 August Thienemann a German zoologist and Einar Naumann a Swedish botanist co founded the International Society of Limnology SIL from Societas Internationalis Limnologiae Forel s original definition of limnology the oceanography of lakes was expanded to encompass the study of all inland waters 2 and influenced Benedykt Dybowski s work on Lake Baikal Prominent early American limnologists included G Evelyn Hutchinson and Ed Deevey 10 At the University of Wisconsin Madison Edward A Birge Chancey Juday Charles R Goldman and Arthur D Hasler contributed to the development of the Center for Limnology 11 12 General limnology EditPhysical properties Edit Physical properties of aquatic ecosystems are determined by a combination of heat currents waves and other seasonal distributions of environmental conditions 13 The morphometry of a body of water depends on the type of feature such as a lake river stream wetland estuary etc and the structure of the earth surrounding the body of water Lakes for instance are classified by their formation and zones of lakes are defined by water depth 14 15 River and stream system morphometry is driven by underlying geology of the area as well as the general velocity of the water 13 Stream morphometry is also influenced by topography especially slope as well as precipitation patterns and other factors such as vegetation and land development Connectivity between streams and lakes relates to the landscape drainage density lake surface area and lake shape 15 Other types of aquatic systems which fall within the study of limnology are estuaries Estuaries are bodies of water classified by the interaction of a river and the ocean or sea 13 Wetlands vary in size shape and pattern however the most common types marshes bogs and swamps often fluctuate between containing shallow freshwater and being dry depending on the time of year 13 Light interactions Edit Light zonation is the concept of how the amount of sunlight penetration into water influences the structure of a body of water 13 These zones define various levels of productivity within an aquatic ecosystems such as a lake For instance the depth of the water column which sunlight is able to penetrate and where most plant life is able to grow is known as the photic or euphotic zone The rest of the water column which is deeper and does not receive sufficient amounts of sunlight for plant growth is known as the aphotic zone 13 Thermal stratification Edit Similar to light zonation thermal stratification or thermal zonation is a way of grouping parts of the water body within an aquatic system based on the temperature of different lake layers The less turbid the water the more light is able to penetrate and thus heat is conveyed deeper in the water 16 Heating declines exponentially with depth in the water column so the water will be warmest near the surface but progressively cooler as moving downwards There are three main sections that define thermal stratification in a lake The epilimnion is closest to the water surface and absorbs long and shortwave radiation to warm the water surface During cooler months wind shear can contribute to cooling of the water surface The thermocline is an area within the water column where water temperatures rapidly decrease 16 The bottom layer is the hypolimnion which tends to have the coldest water because its depth restricts sunlight from reaching it 16 In temperate lakes fall season cooling of surface water results in turnover of the water column where the thermocline is disrupted and the lake temperature profile becomes more uniform In cold climates when water cools below 4oC the temperature of maximum density many lakes can experience an inverse thermal stratification in winter 17 These lakes are often dimictic with a brief spring overturn in addition to longer fall overturn The relative thermal resistance is the energy needed to mix these strata of different temperatures 18 Lake Heat Budget Edit An annual heat budget also shown as 8a is the total amount of heat needed to raise the water from its minimum winter temperature to its maximum summer temperature This can be calculated by integrating the area of the lake at each depth interval Az multiplied by the difference between the summer 8sz and winter 8wz temperatures or displaystyle displaystyle int Az 8sz 8wz 18 Chemical properties Edit The chemical composition of water in aquatic ecosystems is influenced by natural characteristics and processes including precipitation underlying soil and bedrock in the drainage basin erosion evaporation and sedimentation 13 All bodies of water have a certain composition of both organic and inorganic elements and compounds Biological reactions also affect the chemical properties of water In addition to natural processes human activities strongly influence the chemical composition of aquatic systems and their water quality 16 Allochthonous sources of carbon or nutrients come from outside the aquatic system such as plant and soil material Carbon sources from within the system such as algae and the microbial breakdown of aquatic particulate organic carbon are autochthonous In aquatic food webs the portion of biomass derived from allochthonous material is then named allochthony 19 In streams and small lakes allochthonous sources of carbon are dominant while in large lakes and the ocean autochthonous sources dominate 20 Oxygen and carbon dioxide Edit Dissolved oxygen and dissolved carbon dioxide are often discussed together due their coupled role in respiration and photosynthesis Dissolved oxygen concentrations can be altered by physical chemical and biological processes and reaction Physical processes including wind mixing can increase dissolved oxygen concentrations particularly in surface waters of aquatic ecosystems Because dissolved oxygen solubility is linked to water temperatures changes in temperature affect dissolved oxygen concentrations as warmer water has a lower capacity to hold oxygen as colder water 21 Biologically both photosynthesis and aerobic respiration affect dissolved oxygen concentrations 16 Photosynthesis by autotrophic organisms such as phytoplankton and aquatic algae increases dissolved oxygen concentrations while simultaneously reducing carbon dioxide concentrations since carbon dioxide is taken up during photosynthesis 21 All aerobic organisms in the aquatic environment take up dissolved oxygen during aerobic respiration while carbon dioxide is released as a byproduct of this reaction Because photosynthesis is light limited both photosynthesis and respiration occur during the daylight hours while only respiration occurs during dark hours or in dark portions of an ecosystem The balance between dissolved oxygen production and consumption is calculated as the aquatic metabolism rate 22 Lake cross sectional diagram of the factors influencing lake metabolic rates and concentration of dissolved gases within lakes Processes in gold text consume oxygen and produce carbon dioxide while processes in green text produce oxygen and consume carbon dioxide Vertical changes in the concentrations of dissolved oxygen are affected by both wind mixing of surface waters and the balance between photosynthesis and respiration of organic matter These vertical changes known as profiles are based on similar principles as thermal stratification and light penetration As light availability decreases deeper in the water column photosynthesis rates also decrease and less dissolved oxygen is produced This means that dissolved oxygen concentrations generally decrease as you move deeper into the body of water because of photosynthesis is not replenishing dissolved oxygen that is being taken up through respiration 16 During periods of thermal stratification water density gradients prevent oxygen rich surface waters from mixing with deeper waters Prolonged periods of stratification can result in the depletion of bottom water dissolved oxygen when dissolved oxygen concentrations are below 2 milligrams per liter waters are considered hypoxic 21 When dissolved oxygen concentrations are approximately 0 milligrams per liter conditions are anoxic Both hypoxic and anoxic waters reduce available habitat for organisms that respire oxygen and contribute to changes in other chemical reactions in the water 21 Nitrogen and phosphorus Edit Nitrogen and phosphorus are ecologically significant nutrients in aquatic systems Nitrogen is generally present as a gas in aquatic ecosystems however most water quality studies tend to focus on nitrate nitrite and ammonia levels 13 Most of these dissolved nitrogen compounds follow a seasonal pattern with greater concentrations in the fall and winter months compared to the spring and summer 13 Phosphorus has a different role in aquatic ecosystems as it is a limiting factor in the growth of phytoplankton because of generally low concentrations in the water 13 Dissolved phosphorus is also crucial to all living things is often very limiting to primary productivity in freshwater and has its own distinctive ecosystem cycling 16 Biological properties Edit Lake George New York United States an oligotrophic lake Role in ecology Edit Lakes are relatively easy to sample because they have clear cut boundaries compared to terrestrial ecosystems and because field experiments are relatively easy to perform which make then especially useful for ecologists who try to understand ecological dynamics 23 Lake trophic classification Edit One way to classify lakes or other bodies of water is with the trophic state index 2 An oligotrophic lake is characterized by relatively low levels of primary production and low levels of nutrients A eutrophic lake has high levels of primary productivity due to very high nutrient levels Eutrophication of a lake can lead to algal blooms Dystrophic lakes have high levels of humic matter and typically have yellow brown tea coloured waters 2 These categories do not have rigid specifications the classification system can be seen as more of a spectrum encompassing the various levels of aquatic productivity Professional organizations EditPeople who study limnology are called limnologists These scientists largely study the characteristics of inland fresh water systems such as lakes rivers streams ponds and wetlands They may also study non oceanic bodies of salt water such as the Great Salt Lake There are many professional organizations related to limnology and other aspects of the aquatic science including the Association for the Sciences of Limnology and Oceanography the Asociacion Iberica de Limnologia the International Society of Limnology the Polish Limnological Society the Society of Canadian Limnologists and the Freshwater Biological Association See also Edit Lakes portal Rivers portal Wetlands portalHydrology Science of the movement distribution and quality of water on Earth and other planets Lake ecosystem also known as Lentic ecosystems Type of ecosystem Limnological tower Structure for the study of aquatic ecosystems River ecosystem also known as Lotic ecosystems Type of aquatic ecosystem with flowing freshwater Paleolimnology Scientific study of ancient lakes and streamsReferences Edit Kumar Arvind 2005 Fundamentals of Limnology APH Publishing ISBN 9788176489195 a b c d Wetzel R G 2001 Limnology Lake and River Ecosystems 3rd ed Academic Press ISBN 0 12 744760 1 page needed Marsh G Alex Fairbridge Rhodes W 1999 Lentic and lotic ecosystems Environmental Geology Dordrecht Springer Netherlands pp 381 388 doi 10 1007 1 4020 4494 1 204 ISBN 978 1 4020 4494 6 retrieved 2022 04 21 Downing John A January 2009 Global limnology up scaling aquatic services and processes to planet Earth SIL Proceedings 1922 2010 30 8 1149 1166 doi 10 1080 03680770 2009 11923903 S2CID 131488888 Cole J J Prairie Y T Caraco N F McDowell W H Tranvik L J Striegl R G Duarte C M Kortelainen P Downing J A Middelburg J J Melack J 23 May 2007 Plumbing the Global Carbon Cycle Integrating Inland Waters into the Terrestrial Carbon Budget Ecosystems 10 1 172 185 CiteSeerX 10 1 1 177 3527 doi 10 1007 s10021 006 9013 8 S2CID 1728636 Tranvik Lars J Downing John A Cotner James B Loiselle Steven A Striegl Robert G Ballatore Thomas J Dillon Peter Finlay Kerri Fortino Kenneth Knoll Lesley B Kortelainen Pirkko L Kutser Tiit Larsen Soren Laurion Isabelle Leech Dina M McCallister S Leigh McKnight Diane M Melack John M Overholt Erin Porter Jason A Prairie Yves Renwick William H Roland Fabio Sherman Bradford S Schindler David W Sobek Sebastian Tremblay Alain Vanni Michael J Verschoor Antonie M von Wachenfeldt Eddie Weyhenmeyer Gesa A November 2009 Lakes and reservoirs as regulators of carbon cycling and climate Limnology and Oceanography 54 6part2 2298 2314 Bibcode 2009LimOc 54 2298T doi 10 4319 lo 2009 54 6 part 2 2298 hdl 10852 11601 Raymond Peter A Hartmann Jens Lauerwald Ronny Sobek Sebastian McDonald Cory Hoover Mark Butman David Striegl Robert Mayorga Emilio Humborg Christoph Kortelainen Pirkko Durr Hans Meybeck Michel Ciais Philippe Guth Peter 21 November 2013 Global carbon dioxide emissions from inland waters Nature 503 7476 355 359 Bibcode 2013Natur 503 355R doi 10 1038 nature12760 PMID 24256802 S2CID 4460910 Engel Fabian Farrell Kaitlin J McCullough Ian M Scordo Facundo Denfeld Blaize A Dugan Hilary A de Eyto Elvira Hanson Paul C McClure Ryan P Noges Peeter Noges Tiina Ryder Elizabeth Weathers Kathleen C Weyhenmeyer Gesa A 26 March 2018 A lake classification concept for a more accurate global estimate of the dissolved inorganic carbon export from terrestrial ecosystems to inland waters The Science of Nature 105 3 25 Bibcode 2018SciNa 105 25E doi 10 1007 s00114 018 1547 z PMC 5869952 PMID 29582138 O Reilly Catherine M Sharma Sapna Gray Derek K Hampton Stephanie E Read Jordan S Rowley Rex J Schneider Philipp Lenters John D McIntyre Peter B Kraemer Benjamin M Weyhenmeyer Gesa A Straile Dietmar Dong Bo Adrian Rita Allan Mathew G Anneville Orlane Arvola Lauri Austin Jay Bailey John L Baron Jill S Brookes Justin D Eyto Elvira de Dokulil Martin T Hamilton David P Havens Karl Hetherington Amy L Higgins Scott N Hook Simon Izmest eva Lyubov R Joehnk Klaus D Kangur Kulli Kasprzak Peter Kumagai Michio Kuusisto Esko Leshkevich George Livingstone David M MacIntyre Sally May Linda Melack John M Mueller Navarra Doerthe C Naumenko Mikhail Noges Peeter Noges Tiina North Ryan P Plisnier Pierre Denis Rigosi Anna Rimmer Alon Rogora Michela Rudstam Lars G Rusak James A Salmaso Nico Samal Nihar R Schindler Daniel E Schladow S Geoffrey Schmid Martin Schmidt Silke R Silow Eugene Soylu M Evren Teubner Katrin Verburg Piet Voutilainen Ari Watkinson Andrew Williamson Craig E Zhang Guoqing 2015 Rapid and highly variable warming of lake surface waters around the globe Geophysical Research Letters 42 24 10 773 10 781 Bibcode 2015GeoRL 4210773O doi 10 1002 2015gl066235 Frey D G ed 1963 Limnology in North America University of Wisconsin Press Madison History of Limnology UW Digital Collections Retrieved 2019 05 02 Beckel Annamarie L Breaking new waters a century of limnology at the University of Wisconsin Special issue a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help a b c d e f g h i j Horne Alexander J Goldman Charles R 1994 Limnology Second ed United States of America McGraw Hill ISBN 978 0 07 023673 8 page needed Welch P S 1935 Limnology Zoological Science Publications United States of America McGraw Hill ISBN 978 0 07 069179 7 page needed a b Seekell D Cael B Lindmark E Bystrom P 2021 The Fractal Scaling Relationship for River Inlets to Lakes Geophysical Research Letters 48 9 e2021GL093366 Bibcode 2021GeoRL 4893366S doi 10 1029 2021GL093366 ISSN 1944 8007 S2CID 235508504 a b c d e f g Boyd Claude E 2015 Water Quality An Introduction Second ed Switzerland Springer ISBN 978 3 319 17445 7 page needed Yang Bernard Wells Mathew G McMeans Bailey C Dugan Hilary A Rusak James A Weyhenmeyer Gesa A Brentrup Jennifer A Hrycik Allison R Laas Alo Pilla Rachel M Austin Jay A 2021 A New Thermal Categorization of Ice Covered Lakes Geophysical Research Letters 48 3 e2020GL091374 Bibcode 2021GeoRL 4891374Y doi 10 1029 2020GL091374 ISSN 1944 8007 S2CID 233921281 a b Wetzel R G 2001 Limnology Lake and river ecosystems San Diego Academic Press page needed p74 86 Grosbois G del Giorgio P A amp Rautio M 2017 Zooplankton allochthony is spatially heterogeneous in a boreal lake Freshwat Biol 62 474 490 Eby G N 2004 Principles of Environmental Geochemistry Thomson Brooks Cole Pacific Grove CA 514 pp a b c d Dodds Walter K 2010 Freshwater ecology concepts and environmental applications of limnology Whiles Matt R 2nd ed Burlington MA Academic Press ISBN 9780123747242 OCLC 784140625 page needed Cole Jonathan J Caraco Nina F 2001 Carbon in catchments connecting terrestrial carbon losses with aquatic metabolism Marine and Freshwater Research 52 1 101 doi 10 1071 mf00084 S2CID 11143190 Lampert W amp Sommer U 2007 Limnoecology Further reading EditGerald A Cole Textbook of Limnology 4th ed Waveland Press 1994 ISBN 0 88133 800 1 Stanley Dodson Introduction to Limnology 2005 ISBN 0 07 287935 1 A J Horne and C R Goldman Limnology 1994 ISBN 0 07 023673 9 G E Hutchinson A Treatise on Limnology 3 vols 1957 1975 classic but dated H B N Hynes The Ecology of Running Waters 1970 Jacob Kalff Limnology Prentice Hall 2001 B Moss Ecology of Fresh Waters Blackwell 1998 Robert G Wetzel and Gene E Likens Limnological Analyses 3rd ed Springer Verlag 2000 Patrick E O Sullivan and Colin S Reynolds The Lakes Handbook Limnology and limnetic ecology ISBN 0 632 04797 6 Retrieved from https en wikipedia org w index php title Limnology amp oldid 1130276649, wikipedia, wiki, book, books, library,

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