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== Definition ==
== Definition ==
'''Eutrophication''', sometimes known as hypertrophication, is the process by which a body of water becomes enriched in dissolved nutrients (such as phosphates) through the intense breakdown of soil sediments that stimulate the growth of aquatic plant life. This will usually lead to the depletion of dissolved oxygen which is known as hypoxia. [1] This phenomena is perfectly fine when it happens at normal rates, but not at the rates that we are currently witnessing. [[File:cultural_eutrophication.jpg|400px|thumb|left]]
'''Eutrophication''' is the process of excessive nutrients building up in a body of water and resulting in the dense growth of aquatic plants and algae. This leads to the depletion of dissolved oxygen in that body of water. The most common nutrients involved in eutrophication are nitrogen and phosphates. A lack of dissolved oxygen often results in the death of many [[organisms]] that rely on higher concentrations of oxygen in the water. [1]
 
== Causes ==
== Causes ==
While eutrophication is usually a natural process that takes place over the course of hundreds of years, it has in recent decades been negatively influenced and accelerated due to human influence. Naturally occurring eutrophication happens on geologic time scales, [3] but as mentioned, that is no longer the case in most places of the world due to anthropogenic or cultural eutrophication. Cultural eutrophication occurs through either non-point source or point source pollution at the hands of humans. [2] Examples of point-source or non-point source pollution that increase the rates of eutrophication can include, detergents, fertilizers, or sewage which can come from almost anywhere whether it be parking lots and roads or agricultural fields. [3][4]  The most problematic of these tends to be the fertilizers that are used primarily in the cultivation of agricultural fields and grass lawnsNot to mention, clearing of land as well as the building of cities and towns leads to sediment runoff which worsens the rates that phosphates and nitrates make their way into bodies of water. [5] [[File:126077-050-117592F5.jpg|200px|thumb|right]]
Eutrophication occurs naturally over many years but can be accelerated by human activities - a phenomenon known as cultural eutrophication. Of these anthropogenic activities, agricultural runoff from fertilizers and the dumping of wastewater are some of the leading causes of cultural eutrophication. Normally, phosphorus or nitrogen concentrations in the water are low enough to prevent aquatic plants or algae from growing out of control. However, fertilizers are designed to be rich in phosphates or nitrogen (plant specific) to aid in the growth of crops and produce higher yieldsNatural events, such as rain, can carry these chemicals via runoff to ponds or lakes which effectively removes the limiting growth factor of the local plant and algae population allowing exponential growth. [13]
 
[[File:126077-050-117592F5.jpg|200px|thumb|right]]
 
== Consequences ==
== Consequences ==
Because of this sudden flux of nutrients, plant life, especially algae, are permitted to flourish.  It is when these organisms die though that they become decomposed and it is in this decomposition process that oxygen is consumed which in turn reduces the oxygen concentration in the water.  The lack of oxygen in the water of course greatly reduces the number of fish and other animals in said aquatic ecosystem as well as the overall biodiversity. To make matters even worse, the dead algae and other plant material can settle at the bottom of the body of water where it will undergo anaerobic digestion.  This anaerobic digestion releases greenhouse gases like that of methane and carbon dioxide which are incredibly harmful to the atmosphere and the Earth as a whole. [6]  Because of the large scale displacement of sediment, cultural eutrophication is extremely detrimental to the integrity of terrestrial soil habitats as well. [[File:eutrofizzazione.jpg|300px|thumb|right|]]
This rapid increase in plant and algae population produce harmful algal blooms that pose serious threats to more than just the quality of water. Some algal blooms release toxins that can kill fish, birds, and mammals that drink the effected water causing detriment to the entire ecosystem. In extreme cases, these toxins may even cause severe human illness or death. [12] While not all algal species are toxic, algae reduce the levels of dissolved oxygen when they die and enter through the [[decomposition]] process. In turn, this lack of available oxygen within the water affects the ability of many fish as well as other aquatic [[animals]] and plants to survive within the ecosystem. Overall biodiversity can be lowered as a result and significantly modify the local food chain. Furthermore, the dead algae and other plant material will often settle at the bottom of the body of water where it will undergo anaerobic digestion.  This anaerobic digestion releases greenhouse gases like methane and carbon dioxide which are incredibly harmful to the atmosphere and the Earth as a whole. [6]  Because of the large-scale displacement of sediment, cultural eutrophication is extremely detrimental to the integrity of terrestrial [[soil]] habitats as well. [[File:eutrofizzazione.jpg|300px|thumb|right|]]


== Prevention & Reversal ==  
== Prevention & Reversal ==  
Despite its ability to devastate marine habitats, cultural eutrophication can be slowed and even reversed. There have been phosphorus removal measures taken in Finland which have been said to have had a 90% success rate. [7]  Others have proposed encouraging the growth of shellfish populations due to the fact that these organisms take nitrogen out of the water, acting as natural filters and reducing the likelihood of algal blooms.[8]  Reducing the harmful effects of non-point source pollution are some of the most widely supported methods of slowing the rates of eutrophication. Some of these methods include riparian buffer zones and organic farming.  
Despite its ability to devastate marine habitats, cultural eutrophication can be slowed and potentially reversed. There have been phosphorus removal measures taken in Finland which have been said to have had a 90% success rate. [7]  Others have proposed encouraging the growth of shellfish populations because these organisms take nitrogen out of the water, acting as natural filters and reducing the likelihood of algal blooms.[8]  Reducing the harmful effects of non-point source pollution is one of the most widely supported strategies for slowing the rates of eutrophication. Some of these methods include riparian buffer zones and organic farming.  


'''Buffer Zones'''
'''Buffer Zones'''   [[File:220px-Riparian_buffer_on_Bear_Creek_in_Story_County,_Iowa.JPG|200px|thumb|right]]


Buffer zones, specifically riparian buffer zones, are meant to act as a filter to prevent non-point source pollution from contaminating a water source in the first place. [9]  Rather than being a man-made structure, a riparian buffer zone is an area of natural vegetation along the bank of the stream/river[10] like that of a mangrove forest in Southern Florida. [[File:220px-Riparian_buffer_on_Bear_Creek_in_Story_County,_Iowa.JPG]]
Buffer zones, specifically riparian buffer zones, are meant to act as a filter to prevent non-point source pollution from contaminating a water source in the first place. [9]  Rather than being a man-made structure, a riparian buffer zone is an area of natural vegetation along the bank of the stream/river[10] like that of a mangrove forest in Southern Florida.




'''Organic Farming'''     
'''Organic Farming'''     
Organic farming is said to be another very effective method of slowing the rates of anthropogenic eutrophication due the non-existent use of synthetic, nitrogen rich fertilizers.  A study found that fields that were fertilized through organic means were not nearly as harmful as more conventional farming practices in terms of nitrate leaching.[11] [[File:organic farming.jpg|300px|thumb]]


Organic farming is said to be another very effective method for slowing the rates of anthropogenic eutrophication due to the non-existent use of synthetic, nitrogen-rich fertilizers.  A study found that fields that were fertilized through organic means were not nearly as harmful as more conventional farming practices in terms of nitrate leaching.[11]


== References ==
== References ==
1. Eutrophication. (n.d.). . Merriam-Webster. https://www.merriam-webster.com/dictionary/eutrophication.
1. Eutrophication. (n.d.). Merriam-Webster. https://www.merriam-webster.com/dictionary/eutrophication.


2. Chislock, M. F., Doster, E., Zitomer, R. A. & Wilson, A. E. (2013) Eutrophication: Causes, Consequences, and Controls in Aquatic Ecosystems. Nature Education Knowledge 4(4):10
2. Chislock, M. F., Doster, E., Zitomer, R. A. & Wilson, A. E. (2013) Eutrophication: Causes, Consequences, and Controls in Aquatic Ecosystems. Nature Education Knowledge 4(4):10
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6. Tittmann, A., n.d. Climate gases from water bodies [WWW Document]. IGB. URL https://www.igb-berlin.de/en/news/climate-gases-water-bodies
6. Tittmann, A., n.d. Climate gases from water bodies [WWW Document]. IGB. URL https://www.igb-berlin.de/en/news/climate-gases-water-bodies


7.  Räike, A.; Pietiläinen, O. -P.; Rekolainen, S.; Kauppila, P.; Pitkänen, H.; Niemi, J.; Raateland, A.; Vuorenmaa, J. (2003). "Trends of phosphorus, nitrogen and chlorophyll a concentrations in Finnish rivers and lakes in 1975–2000". Science of the Total Environment. 310 (1–3): 47–59. Bibcode:2003ScTEn.310...47R. doi:10.1016/S0048-9697(02)00622-8. PMID 12812730.
7.  Räike, A.; Pietiläinen, O. -P.; Rekolainen, S.; Kauppila, P.; Pitkänen, H.; Niemi, J.; Raateland, A.; Vuorenmaa, J. (2003). "Trends of phosphorus, nitrogen and chlorophyll concentrations in Finnish rivers and lakes in 1975–2000". Science of the Total Environment. 310 (1–3): 47–59. Bibcode:2003ScTEn.310...47R. doi:10.1016/S0048-9697(02)00622-8. PMID 12812730.


8. Kroeger, Timm (2012) Dollars and Sense: Economic Benefits and Impacts from two Oyster Reef Restoration Projects in the Northern Gulf of Mexico Archived 2016-03-04 at the Wayback Machine. TNC Report.
8. Kroeger, Timm (2012) Dollars and Sense: Economic Benefits and Impacts from two Oyster Reef Restoration Projects in the Northern Gulf of Mexico Archived 2016-03-04 at the Wayback Machine. TNC Report.
Line 41: Line 44:


11. Kramer, S. B. (2006). "Reduced nitrate leaching and enhanced denitrifier activity and efficiency in organically fertilized soils". Proceedings of the National Academy of Sciences. 103 (12): 4522–4527. Bibcode:2006PNAS..103.4522K. doi:10.1073/pnas.0600359103. PMC 1450204. PMID 16537377.
11. Kramer, S. B. (2006). "Reduced nitrate leaching and enhanced denitrifier activity and efficiency in organically fertilized soils". Proceedings of the National Academy of Sciences. 103 (12): 4522–4527. Bibcode:2006PNAS..103.4522K. doi:10.1073/pnas.0600359103. PMC 1450204. PMID 16537377.
12. Morris, J. G. Harmful algal blooms: an emerging public health problem with possible links to human stress on the environment. Annual review of Energy and the Environment 24, 367-390 (1990)
13. Michael F. Chislock (2013) Eutrophication Causes, Consequences, and Controls in Aquatic Ecosystems - Nature Education

Latest revision as of 14:42, 10 March 2023

Definition

Eutrophication is the process of excessive nutrients building up in a body of water and resulting in the dense growth of aquatic plants and algae. This leads to the depletion of dissolved oxygen in that body of water. The most common nutrients involved in eutrophication are nitrogen and phosphates. A lack of dissolved oxygen often results in the death of many organisms that rely on higher concentrations of oxygen in the water. [1]

Causes

Eutrophication occurs naturally over many years but can be accelerated by human activities - a phenomenon known as cultural eutrophication. Of these anthropogenic activities, agricultural runoff from fertilizers and the dumping of wastewater are some of the leading causes of cultural eutrophication. Normally, phosphorus or nitrogen concentrations in the water are low enough to prevent aquatic plants or algae from growing out of control. However, fertilizers are designed to be rich in phosphates or nitrogen (plant specific) to aid in the growth of crops and produce higher yields. Natural events, such as rain, can carry these chemicals via runoff to ponds or lakes which effectively removes the limiting growth factor of the local plant and algae population allowing exponential growth. [13]

126077-050-117592F5.jpg

Consequences

This rapid increase in plant and algae population produce harmful algal blooms that pose serious threats to more than just the quality of water. Some algal blooms release toxins that can kill fish, birds, and mammals that drink the effected water causing detriment to the entire ecosystem. In extreme cases, these toxins may even cause severe human illness or death. [12] While not all algal species are toxic, algae reduce the levels of dissolved oxygen when they die and enter through the decomposition process. In turn, this lack of available oxygen within the water affects the ability of many fish as well as other aquatic animals and plants to survive within the ecosystem. Overall biodiversity can be lowered as a result and significantly modify the local food chain. Furthermore, the dead algae and other plant material will often settle at the bottom of the body of water where it will undergo anaerobic digestion. This anaerobic digestion releases greenhouse gases like methane and carbon dioxide which are incredibly harmful to the atmosphere and the Earth as a whole. [6] Because of the large-scale displacement of sediment, cultural eutrophication is extremely detrimental to the integrity of terrestrial soil habitats as well.

Eutrofizzazione.jpg

Prevention & Reversal

Despite its ability to devastate marine habitats, cultural eutrophication can be slowed and potentially reversed. There have been phosphorus removal measures taken in Finland which have been said to have had a 90% success rate. [7] Others have proposed encouraging the growth of shellfish populations because these organisms take nitrogen out of the water, acting as natural filters and reducing the likelihood of algal blooms.[8] Reducing the harmful effects of non-point source pollution is one of the most widely supported strategies for slowing the rates of eutrophication. Some of these methods include riparian buffer zones and organic farming.

Buffer Zones

220px-Riparian buffer on Bear Creek in Story County, Iowa.JPG

Buffer zones, specifically riparian buffer zones, are meant to act as a filter to prevent non-point source pollution from contaminating a water source in the first place. [9] Rather than being a man-made structure, a riparian buffer zone is an area of natural vegetation along the bank of the stream/river[10] like that of a mangrove forest in Southern Florida.


Organic Farming

Organic farming is said to be another very effective method for slowing the rates of anthropogenic eutrophication due to the non-existent use of synthetic, nitrogen-rich fertilizers. A study found that fields that were fertilized through organic means were not nearly as harmful as more conventional farming practices in terms of nitrate leaching.[11]

References

1. Eutrophication. (n.d.). Merriam-Webster. https://www.merriam-webster.com/dictionary/eutrophication.

2. Chislock, M. F., Doster, E., Zitomer, R. A. & Wilson, A. E. (2013) Eutrophication: Causes, Consequences, and Controls in Aquatic Ecosystems. Nature Education Knowledge 4(4):10

3. Callisto, Marcos; Molozzi, Joseline and Barbosa, José Lucena Etham (2014) "Eutrophication of Lakes" in A. A. Ansari, S. S. Gill (eds.), Eutrophication: Causes, Consequences and Control, Springer Science+Business Media Dordrecht. doi:10.1007/978-94-007-7814-6_5. ISBN 978-94-007-7814-6.

4. Muir, P., 2012. Eutrophication [WWW Document]. Oregon State University. URL http://people.oregonstate.edu/~muirp/eutrophi.htm

5. Schindler, David W., Vallentyne, John R. (2008). The Algal Bowl: Overfertilization of the World's Freshwaters and Estuaries, University of Alberta Press, ISBN 0-88864-484-1.

6. Tittmann, A., n.d. Climate gases from water bodies [WWW Document]. IGB. URL https://www.igb-berlin.de/en/news/climate-gases-water-bodies

7. Räike, A.; Pietiläinen, O. -P.; Rekolainen, S.; Kauppila, P.; Pitkänen, H.; Niemi, J.; Raateland, A.; Vuorenmaa, J. (2003). "Trends of phosphorus, nitrogen and chlorophyll concentrations in Finnish rivers and lakes in 1975–2000". Science of the Total Environment. 310 (1–3): 47–59. Bibcode:2003ScTEn.310...47R. doi:10.1016/S0048-9697(02)00622-8. PMID 12812730.

8. Kroeger, Timm (2012) Dollars and Sense: Economic Benefits and Impacts from two Oyster Reef Restoration Projects in the Northern Gulf of Mexico Archived 2016-03-04 at the Wayback Machine. TNC Report.

9. Carpenter, S.R.; Caraco, N.F.; Smith, V.H. (1998). "Nonpoint pollution of surface waters with phosphorus and nitrogen". Ecological Applications. 8 (3): 559–568. doi:10.2307/2641247. hdl:1813/60811. JSTOR 2641247.

10. Importance of Riparian Buffers. 2019. . https://dep.wv.gov/WWE/getinvolved/sos/Pages/RiparianMagic.aspx.

11. Kramer, S. B. (2006). "Reduced nitrate leaching and enhanced denitrifier activity and efficiency in organically fertilized soils". Proceedings of the National Academy of Sciences. 103 (12): 4522–4527. Bibcode:2006PNAS..103.4522K. doi:10.1073/pnas.0600359103. PMC 1450204. PMID 16537377.

12. Morris, J. G. Harmful algal blooms: an emerging public health problem with possible links to human stress on the environment. Annual review of Energy and the Environment 24, 367-390 (1990)

13. Michael F. Chislock (2013) Eutrophication Causes, Consequences, and Controls in Aquatic Ecosystems - Nature Education