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Biodiversity in agriculture

January 01, 1970

Biodiversity in agriculture is the measure of biodiversity found on agricultural land. Biodiversity is the total diversity of species present in an area at all levels of biological organization.[1] It is characterized by heterogeneous habitats that support the diverse ecological structure.[1] In agricultural areas, biodiversity decreases as varying landscapes are lost and native plants are replaced with cultivated crops.[1] Increasing biodiversity in agriculture can increase the sustainability of farms through the restoration of ecosystem services that aid in regulating agricultural lands.[2] Biodiversity in agriculture can be increased through the process of agroecological restoration, as farm biodiversity is an aspect of agroecology.

Agricultural lands with large areas of monoculture lacking heterogeneity.

Biodiversity is the measure of biotic and abiotic diversity in an ecosystem, described by heterogeneity.[1] The loss of biodiversity in agriculture has been an increasing issue since the global increase of food demands and success of popular crops.[3][4] This loss of heterogeneity declines species biodiversity on agricultural lands.[5] Biodiversity in agriculture is essential in providing ecosystem services, which conserves biodiversity while providing agricultural services.[6]

Biodiversity loss edit

Agriculture creates a conflict over the use of land between wildlife and humans.[7] Land use for agriculture has been a driving force in creating biodiversity loss[8] An increase in the amount of pasture and crop land over the last few hundred years has led to the rapid loss of natural habitats.[7] The Food and Agriculture Organization of the United Nations estimates that more than 40% of Earth's land surface is currently used for agriculture. Because so much land has been converted to agriculture, habitat loss is recognized as the driving force in biodiversity loss.[9] A decline in farmland biodiversity can be traced to changes in farming practices and increased agricultural intensity.[3]: 182  Nonetheless, according to the FAO, "biodiversity is just as important on farms and in fields as it is in deep river valleys or mountain cloud forests".[10] In recent years, the world has acknowledged the value of biodiversity through treaties formed, such as in the 1992 Convention on Biological Diversity.[10]

 
Monoculture results in the loss of biodiversity, as it prioritizes cultivated crops over native plants.

The loss of habitat connectivity caused by fragmentation in agricultural areas threatens biodiversity, as it decreases population sizes and restricts its access to external resources.[11] Species facing habitat fragmentation can also create a genetic bottleneck[12] The decreased gene pool threatens species through factors such as inbreeding depression, where the less advantageous populations lowers the species survival rates.[11] Monoculture is the practice of producing a single crop on a given piece of land, including crop rotation.[12] While monoculture produces optimum yields, it has implications for the biodiversity of farms.[9] Heterogeneity, the diversity of the landscape, has been shown to be associated with species diversity. For example, butterfly abundance has been found to increase with heterogeneity. Land that is not cropped, such as fallow land, grass margins in the spaces between different fields, and strips of scrub along field boundaries increase heterogeneity and thus the biodiversity of a farm. Plants attract insects, which will attract certain species of birds, and those birds will attract their natural predators. The cover provided by non-cropped land allows species to move across the landscape.[3]: 183–184  In Asian rice, one study showed crop diversification by growing flowering crops in strips beside rice fields could reduce pests so that insecticide spraying was reduced by 70%, yields increase by 5%, together resulting in an economic advantage of 7.5%.[13]

The Green Revolution edit

One of the issues facing biodiversity in areas of industrial agriculture is the loss of heterogeneity, described by the loss of a biotic and abiotic diversity.[1][3] Since 1966, the Green Revolution enhanced agricultural productivity through technological, economical, and political advancements in an effort to increase food security globally.[14] This includes the introduction of genetically modified crops, which allows for increased yield, pest resistance, and improved crop varieties.[14] These advancements also led to increased global geographical spread of 52 agricultural crops with cereals such as wheat, rice, and maize showing the greatest increase in the past 50 years.[4] The loss of agricultural heterogeneity decreases local food security due to a loss in crop diversity, despite its accommodation of global food demands.[4]

Heterogeneity edit

Heterogeneity is essential in increasing species heterogeneity, which maintain stable ecological structures essential to providing ecosystem services.[5] Of the features associated with species diversity is land size, where a study proved a relationship between smaller agricultural fields and increased species richness.[15] The area of an agricultural field is associated with organisms accessibility to the edges of the field, which usually allow access for fields with different biophysical and geophysical features.[15] Increased accessibility to a diverse ecological features increases heterogeneity and reduces edge effects on populations inhabiting agricultural fields.[3][15]

Ecosystem services edit

 
Pollinators provide essential ecosystem services.

Agriculture is a transformative process to any habitat, with a main focus on cultivating crops for human consumption.[16] Views on ecosystem services can be presented through viewpoints that benefit humans environmentally, economically, and culturally to motivate the practices that support ecosystem services in the agricultural industry.[16] For example, low crop diversity can increase pests and their resistance to pesticides, resulting in large ecological disturbances and economical losses.[6] This can be mitigated with increased crop rotation, which contributes to more diverse soil microbiota and insects that provide ecosystem services.[6] Another example is the conservation of pollinators such as honeybees that can contribute to the agricultural industry, where contributing to the increase of pollinators is reciprocated with increased crop production.[16]

See also edit

References edit

  1. ^ a b c d e Harlan JR, Gepts P, Famula TR, Bettinger RL, Brush SB, Damania AB, McGuire PE, Qualset CO (2012-02-23). Biodiversity in Agriculture: Domestication, Evolution, and Sustainability. Cambridge University Press. p. 5. ISBN 978-0-521-76459-9.
  2. ^ Duru M, Therond O, Martin G, Martin-Clouaire R, Magne M, Justes E, et al. (October 2015). "How to implement biodiversity-based agriculture to enhance ecosystem services: a review". Agronomy for Sustainable Development. 35 (4): 1259–1281. doi:10.1007/s13593-015-0306-1. ISSN 1773-0155. S2CID 256204561.
  3. ^ a b c d e Benton TG, Vickery JA, Wilson JD (April 2003). "Farmland biodiversity: is habitat heterogeneity the key?". Trends in Ecology & Evolution. 18 (4): 182–188. doi:10.1016/S0169-5347(03)00011-9. ISSN 0169-5347.
  4. ^ a b c Khoury CK, Bjorkman AD, Dempewolf H, Ramirez-Villegas J, Guarino L, Jarvis A, et al. (March 2014). "Increasing homogeneity in global food supplies and the implications for food security". Proceedings of the National Academy of Sciences of the United States of America. 111 (11): 4001–4006. Bibcode:2014PNAS..111.4001K. doi:10.1073/pnas.1313490111. PMC 3964121. PMID 24591623.
  5. ^ a b Martin AE, Collins SJ, Crowe S, Girard J, Naujokaitis-Lewis I, Smith AC, et al. (February 2020). "Effects of farmland heterogeneity on biodiversity are similar to—or even larger than—the effects of farming practices". Agriculture, Ecosystems & Environment. 288: 106698. doi:10.1016/j.agee.2019.106698. ISSN 0167-8809. S2CID 209571087.
  6. ^ a b c Robertson GP, Gross KL, Hamilton SK, Landis DA, Schmidt TM, Snapp SS, Swinton SM (May 2014). "Farming for Ecosystem Services: An Ecological Approach to Production Agriculture". BioScience. 64 (5): 404–415. doi:10.1093/biosci/biu037. PMC 4776676. PMID 26955069.
  7. ^ a b Feber RE, Asteraki EJ, Firbank LG (2007). "Chapter 16: Can Farming and Wildlife Coexist?". In Macdonald DW, Service K (eds.). Key Topics in Conservation Biology. Oxford: Blackwell Publishing. ISBN 978-1-4051-2249-8.
  8. ^ Jackson DL, Jackson LL (2002). "Introduction". The Farm as Natural Habitat. Washington: Island Press. ISBN 978-1-59726-269-9.
  9. ^ a b Jackson LL (2002). "Chapter 10: Restoring Prairie Processes to Farmlands". In Jackson DL, Jackson LL (eds.). The Farm as Natural Habitat. Washington: Island Press. ISBN 978-1-59726-269-9.
  10. ^ a b . FAO Newsroom. Food and Agricultural Organization (FAO). 15 October 2004. Archived from the original on 17 January 2018. Retrieved 28 December 2018.
  11. ^ a b Banaszek A, Jadwiszczak KA, Ziomek J (November 2011). "Genetic variability and differentiation in the Polish common hamster (Cricetus cricetus L.): Genetic consequences of agricultural habitat fragmentation". Mammalian Biology. 76 (6): 665–671. doi:10.1016/j.mambio.2010.10.014. ISSN 1618-1476.
  12. ^ a b Geffen E, Luikart G, Waples RS (2007). "Chapter 4: Impacts of modern molecular genetic techniques on conservation biology". In Macdonald DW, Service K (eds.). Key Topics in Conservation Biology. Oxford: Blackwell Publishing. ISBN 978-1-4051-2249-8.
  13. ^ Gurr GM, Lu Z, Zheng X, Xu H, Zhu P, Chen G, et al. (February 2016). "Multi-country evidence that crop diversification promotes ecological intensification of agriculture". Nature Plants. 2 (3): 16014. doi:10.1038/nplants.2016.14. PMID 27249349. S2CID 205458366.
  14. ^ a b Pingali PL (July 2012). "Green revolution: impacts, limits, and the path ahead". Proceedings of the National Academy of Sciences of the United States of America. 109 (31): 12302–12308. Bibcode:2012PNAS..10912302P. doi:10.1073/pnas.0912953109. PMC 3411969. PMID 22826253.
  15. ^ a b c Boulinier T, Nichols JD, Sauer JR, Hines JE, Pollock KH (April 1998). "Estimating species richness: the importance of heterogeneity in species detectability". Ecology. 79 (3): 1018–1028. doi:10.1890/0012-9658(1998)079[1018:ESRTIO]2.0.CO;2. ISSN 0012-9658.
  16. ^ a b c Swinton SM, Lupi F, Robertson GP, Hamilton SK (2007-12-15). "Ecosystem services and agriculture: Cultivating agricultural ecosystems for diverse benefits". Ecological Economics. Special Section - Ecosystem Services and Agriculture. 64 (2): 245–252. doi:10.1016/j.ecolecon.2007.09.020. ISSN 0921-8009.

Further reading edit

  • Altieri MA (January 1999). "The Ecological Role of Biodiversity in Agroecosystems.". Invertebrate Biodiversity as Bioindicators of Sustainable Landscapes. Elsevier. pp. 19–31. doi:10.1016/B978-0-444-50019-9.50005-4. ISBN 978-0-444-50019-9.
  • Dabbert S (2003). "Organic agriculture and sustainability: Environmental aspects". Organic Agriculture Sustainability, Markets and Policies: Sustainability, Markets and Policies. Paris, France: OECD Publications Service. ISBN 978-9-264-10151-7.
  • Fiedler AK, Landis DA, Wratten SD (May 2008). "Maximizing ecosystem services from conservation biological control: the role of habitat management". Biological Control. 45 (2): 254–271. doi:10.1016/j.biocontrol.2007.12.009.
  • Hole DG, Perkins AJ, Wilson JD, Alexander IH, Grice PV, Evans AD (March 2005). "Does organic farming benefit biodiversity?". Biological Conservation. 122 (1): 113–130. doi:10.1016/j.biocon.2004.07.018. ISSN 0006-3207.
  • Leopold A (1939). "The Farmer as a Conservationist". In Flader SL, Callicott JB (eds.). The River of the Mother of God. Madison WI: University of Wisconsin Press. pp. 255–265.
  • Schmidt MH, Tscharntke T (January 2005). "The role of perennial habitats for Central European farmland spiders". Agriculture, Ecosystems & Environment. 105 (1–2): 235–242. doi:10.1016/j.agee.2004.03.009.
  • Shannon D, Sen AM, Johnson DB (September 2002). "A comparative study of the microbiology of soils managed under organic and conventional regimes". Soil Use and Management. 18: 274–283. doi:10.1111/j.1475-2743.2002.tb00269.x. S2CID 97962676.
  • Zhang W, Ricketts TH, Kremen C, Carney K, Swinton SM (December 2007). "Ecosystem services and dis-services to agriculture". Ecological Economics. 64 (2): 253–260. doi:10.1016/j.ecolecon.2007.02.024.

January 01, 1970
biodiversity, agriculture, measure, biodiversity, found, agricultural, land, biodiversity, total, diversity, species, present, area, levels, biological, organization, characterized, heterogeneous, habitats, that, support, diverse, ecological, structure, agricu. Biodiversity in agriculture is the measure of biodiversity found on agricultural land Biodiversity is the total diversity of species present in an area at all levels of biological organization 1 It is characterized by heterogeneous habitats that support the diverse ecological structure 1 In agricultural areas biodiversity decreases as varying landscapes are lost and native plants are replaced with cultivated crops 1 Increasing biodiversity in agriculture can increase the sustainability of farms through the restoration of ecosystem services that aid in regulating agricultural lands 2 Biodiversity in agriculture can be increased through the process of agroecological restoration as farm biodiversity is an aspect of agroecology Agricultural lands with large areas of monoculture lacking heterogeneity Biodiversity is the measure of biotic and abiotic diversity in an ecosystem described by heterogeneity 1 The loss of biodiversity in agriculture has been an increasing issue since the global increase of food demands and success of popular crops 3 4 This loss of heterogeneity declines species biodiversity on agricultural lands 5 Biodiversity in agriculture is essential in providing ecosystem services which conserves biodiversity while providing agricultural services 6 Contents 1 Biodiversity loss 2 The Green Revolution 3 Heterogeneity 4 Ecosystem services 5 See also 6 References 7 Further readingBiodiversity loss editAgriculture creates a conflict over the use of land between wildlife and humans 7 Land use for agriculture has been a driving force in creating biodiversity loss 8 An increase in the amount of pasture and crop land over the last few hundred years has led to the rapid loss of natural habitats 7 The Food and Agriculture Organization of the United Nations estimates that more than 40 of Earth s land surface is currently used for agriculture Because so much land has been converted to agriculture habitat loss is recognized as the driving force in biodiversity loss 9 A decline in farmland biodiversity can be traced to changes in farming practices and increased agricultural intensity 3 182 Nonetheless according to the FAO biodiversity is just as important on farms and in fields as it is in deep river valleys or mountain cloud forests 10 In recent years the world has acknowledged the value of biodiversity through treaties formed such as in the 1992 Convention on Biological Diversity 10 nbsp Monoculture results in the loss of biodiversity as it prioritizes cultivated crops over native plants The loss of habitat connectivity caused by fragmentation in agricultural areas threatens biodiversity as it decreases population sizes and restricts its access to external resources 11 Species facing habitat fragmentation can also create a genetic bottleneck 12 The decreased gene pool threatens species through factors such as inbreeding depression where the less advantageous populations lowers the species survival rates 11 Monoculture is the practice of producing a single crop on a given piece of land including crop rotation 12 While monoculture produces optimum yields it has implications for the biodiversity of farms 9 Heterogeneity the diversity of the landscape has been shown to be associated with species diversity For example butterfly abundance has been found to increase with heterogeneity Land that is not cropped such as fallow land grass margins in the spaces between different fields and strips of scrub along field boundaries increase heterogeneity and thus the biodiversity of a farm Plants attract insects which will attract certain species of birds and those birds will attract their natural predators The cover provided by non cropped land allows species to move across the landscape 3 183 184 In Asian rice one study showed crop diversification by growing flowering crops in strips beside rice fields could reduce pests so that insecticide spraying was reduced by 70 yields increase by 5 together resulting in an economic advantage of 7 5 13 The Green Revolution editOne of the issues facing biodiversity in areas of industrial agriculture is the loss of heterogeneity described by the loss of a biotic and abiotic diversity 1 3 Since 1966 the Green Revolution enhanced agricultural productivity through technological economical and political advancements in an effort to increase food security globally 14 This includes the introduction of genetically modified crops which allows for increased yield pest resistance and improved crop varieties 14 These advancements also led to increased global geographical spread of 52 agricultural crops with cereals such as wheat rice and maize showing the greatest increase in the past 50 years 4 The loss of agricultural heterogeneity decreases local food security due to a loss in crop diversity despite its accommodation of global food demands 4 Heterogeneity editHeterogeneity is essential in increasing species heterogeneity which maintain stable ecological structures essential to providing ecosystem services 5 Of the features associated with species diversity is land size where a study proved a relationship between smaller agricultural fields and increased species richness 15 The area of an agricultural field is associated with organisms accessibility to the edges of the field which usually allow access for fields with different biophysical and geophysical features 15 Increased accessibility to a diverse ecological features increases heterogeneity and reduces edge effects on populations inhabiting agricultural fields 3 15 Ecosystem services edit nbsp Pollinators provide essential ecosystem services Agriculture is a transformative process to any habitat with a main focus on cultivating crops for human consumption 16 Views on ecosystem services can be presented through viewpoints that benefit humans environmentally economically and culturally to motivate the practices that support ecosystem services in the agricultural industry 16 For example low crop diversity can increase pests and their resistance to pesticides resulting in large ecological disturbances and economical losses 6 This can be mitigated with increased crop rotation which contributes to more diverse soil microbiota and insects that provide ecosystem services 6 Another example is the conservation of pollinators such as honeybees that can contribute to the agricultural industry where contributing to the increase of pollinators is reciprocated with increased crop production 16 See also editAgroecologyReferences edit a b c d e Harlan JR Gepts P Famula TR Bettinger RL Brush SB Damania AB McGuire PE Qualset CO 2012 02 23 Biodiversity in Agriculture Domestication Evolution and Sustainability Cambridge University Press p 5 ISBN 978 0 521 76459 9 Duru M Therond O Martin G Martin Clouaire R Magne M Justes E et al October 2015 How to implement biodiversity based agriculture to enhance ecosystem services a review Agronomy for Sustainable Development 35 4 1259 1281 doi 10 1007 s13593 015 0306 1 ISSN 1773 0155 S2CID 256204561 a b c d e Benton TG Vickery JA Wilson JD April 2003 Farmland biodiversity is habitat heterogeneity the key Trends in Ecology amp Evolution 18 4 182 188 doi 10 1016 S0169 5347 03 00011 9 ISSN 0169 5347 a b c Khoury CK Bjorkman AD Dempewolf H Ramirez Villegas J Guarino L Jarvis A et al March 2014 Increasing homogeneity in global food supplies and the implications for food security Proceedings of the National Academy of Sciences of the United States of America 111 11 4001 4006 Bibcode 2014PNAS 111 4001K doi 10 1073 pnas 1313490111 PMC 3964121 PMID 24591623 a b Martin AE Collins SJ Crowe S Girard J Naujokaitis Lewis I Smith AC et al February 2020 Effects of farmland heterogeneity on biodiversity are similar to or even larger than the effects of farming practices Agriculture Ecosystems amp Environment 288 106698 doi 10 1016 j agee 2019 106698 ISSN 0167 8809 S2CID 209571087 a b c Robertson GP Gross KL Hamilton SK Landis DA Schmidt TM Snapp SS Swinton SM May 2014 Farming for Ecosystem Services An Ecological Approach to Production Agriculture BioScience 64 5 404 415 doi 10 1093 biosci biu037 PMC 4776676 PMID 26955069 a b Feber RE Asteraki EJ Firbank LG 2007 Chapter 16 Can Farming and Wildlife Coexist In Macdonald DW Service K eds Key Topics in Conservation Biology Oxford Blackwell Publishing ISBN 978 1 4051 2249 8 Jackson DL Jackson LL 2002 Introduction The Farm as Natural Habitat Washington Island Press ISBN 978 1 59726 269 9 a b Jackson LL 2002 Chapter 10 Restoring Prairie Processes to Farmlands In Jackson DL Jackson LL eds The Farm as Natural Habitat Washington Island Press ISBN 978 1 59726 269 9 a b The future of agriculture depends on biodiversity FAO Newsroom Food and Agricultural Organization FAO 15 October 2004 Archived from the original on 17 January 2018 Retrieved 28 December 2018 a b Banaszek A Jadwiszczak KA Ziomek J November 2011 Genetic variability and differentiation in the Polish common hamster Cricetus cricetus L Genetic consequences of agricultural habitat fragmentation Mammalian Biology 76 6 665 671 doi 10 1016 j mambio 2010 10 014 ISSN 1618 1476 a b Geffen E Luikart G Waples RS 2007 Chapter 4 Impacts of modern molecular genetic techniques on conservation biology In Macdonald DW Service K eds Key Topics in Conservation Biology Oxford Blackwell Publishing ISBN 978 1 4051 2249 8 Gurr GM Lu Z Zheng X Xu H Zhu P Chen G et al February 2016 Multi country evidence that crop diversification promotes ecological intensification of agriculture Nature Plants 2 3 16014 doi 10 1038 nplants 2016 14 PMID 27249349 S2CID 205458366 a b Pingali PL July 2012 Green revolution impacts limits and the path ahead Proceedings of the National Academy of Sciences of the United States of America 109 31 12302 12308 Bibcode 2012PNAS 10912302P doi 10 1073 pnas 0912953109 PMC 3411969 PMID 22826253 a b c Boulinier T Nichols JD Sauer JR Hines JE Pollock KH April 1998 Estimating species richness the importance of heterogeneity in species detectability Ecology 79 3 1018 1028 doi 10 1890 0012 9658 1998 079 1018 ESRTIO 2 0 CO 2 ISSN 0012 9658 a b c Swinton SM Lupi F Robertson GP Hamilton SK 2007 12 15 Ecosystem services and agriculture Cultivating agricultural ecosystems for diverse benefits Ecological Economics Special Section Ecosystem Services and Agriculture 64 2 245 252 doi 10 1016 j ecolecon 2007 09 020 ISSN 0921 8009 Further reading editAltieri MA January 1999 The Ecological Role of Biodiversity in Agroecosystems Invertebrate Biodiversity as Bioindicators of Sustainable Landscapes Elsevier pp 19 31 doi 10 1016 B978 0 444 50019 9 50005 4 ISBN 978 0 444 50019 9 Dabbert S 2003 Organic agriculture and sustainability Environmental aspects Organic Agriculture Sustainability Markets and Policies Sustainability Markets and Policies Paris France OECD Publications Service ISBN 978 9 264 10151 7 Fiedler AK Landis DA Wratten SD May 2008 Maximizing ecosystem services from conservation biological control the role of habitat management Biological Control 45 2 254 271 doi 10 1016 j biocontrol 2007 12 009 Hole DG Perkins AJ Wilson JD Alexander IH Grice PV Evans AD March 2005 Does organic farming benefit biodiversity Biological Conservation 122 1 113 130 doi 10 1016 j biocon 2004 07 018 ISSN 0006 3207 Leopold A 1939 The Farmer as a Conservationist In Flader SL Callicott JB eds The River of the Mother of God Madison WI University of Wisconsin Press pp 255 265 Schmidt MH Tscharntke T January 2005 The role of perennial habitats for Central European farmland spiders Agriculture Ecosystems amp Environment 105 1 2 235 242 doi 10 1016 j agee 2004 03 009 Shannon D Sen AM Johnson DB September 2002 A comparative study of the microbiology of soils managed under organic and conventional regimes Soil Use and Management 18 274 283 doi 10 1111 j 1475 2743 2002 tb00269 x S2CID 97962676 Zhang W Ricketts TH Kremen C Carney K Swinton SM December 2007 Ecosystem services and dis services to agriculture Ecological Economics 64 2 253 260 doi 10 1016 j ecolecon 2007 02 024 Retrieved from https en wikipedia org w index php title Biodiversity in agriculture amp oldid 1215907656, wikipedia, wiki, book, books, library,

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