Biodiversity in agriculture

Increasing biodiversity in agriculture may increase the sustainability of the farm.

The biodiversity of farms is an aspect of agroecology.

Background[edit]

Agriculture creates a conflict over the use of land between wildlife and humans.^[1] Land use for agriculture has been a driving force in creating biodiversity loss.^[2] The increase in the amount of pasture and crop land over the last few hundred years has led to the rapid loss of natural habitats.^[1] 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.^[3] A decline in farmland biodiversity can be traced to changes in farming practices and increased agricultural intensity.^[4]

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".^[5]

The world has acknowledged the value of biodiversity in treaties in recent years, such as in the 1992 Convention on Biological Diversity.^[5]

Species face habitat fragmentation which can create a genetic bottleneck.^[6] Monoculture, the practice of producing a single crop on a given piece of land, including crop rotation, produces optimum yields, but has implications for the biodiversity of farms.^[7]

Heterogeneity, the diversity of the landscape, has been shown to be associated with species diversity. Butterfly abundance has been found to increase with heterogeneity, for example. Land that is not cropped, such as fallow land, grass margins in the spaces between different fields, and strips of scrub along field boundaries increases heterogeneity, and thus the biodiversity of a farm. The plants attract insects, will which attract certain species of birds, and those birds will attract their natural predators. The cover provided by the uncropped land allows the species to move across the landscape.^[8] 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% (Gurr et al., 2016).

Notes[edit]

^ ^a ^b Macdonald, Key Topics in Conservation Biology, Chapter 16
^ 1.^ Jackson et al., The Farm as Natural Habitat, Introduction
^ 4. Jackson et al., The Farm as Natural Habitat, Ch. 10
^ 5.^ Benton et al., 182
^ ^a ^b "The future of agriculture depends on biodiversity". www.fao.org. Retrieved 2018-12-28.
^ 7.^ Macdonald et al., Key Topics in Conservation Biology, Ch 4
^ 8. Jackson et al., The Farm as Natural Habitat, Ch. 10
^ 6.^ Benton et al., 183–184

References[edit]

Altieri, Miguel A. 1999. The ecological role of biodiversity in agroecosystems: Agriculture, Ecosystemsand Environment 74: 19–31.
Benton, Tim G., Vickery, Juliet A., Wilson, Jeremy D. 2003. Farmland biodiversity: is habitat heterogeneity the key? Trends in Ecology and Evolution 18: 182–188
Dabbert, Stephan, 2002, Organic Agriculture and the Environment. OECD Publications Service
Fiedler, Anna K., Landis, Douglas A., Wratten, Steve D. 2008. Maximizing ecosystem services from conservation biological control: The role of habitat management. Biological Control 45: 254–271
Hole, D.G.; Perkins, A.J.; Wilson, J.D.; Alexander, I.H.; Grice, P.V.; Evans, A.D. (2005-03-01). "Does organic farming benefit biodiversity?". Biological Conservation. 122 (1): 113–130. doi:10.1016/j.biocon.2004.07.018. ISSN 0006-3207.
Jackson, Dana L, Jackson, Laura L. 2002. The Farm as Natural Habitat. Island Press, Washington.
Leopold, Aldo. 1939. The Farmer as a Conservationist. Pages 255–265 in Flader, Susan L., Callicott, J. Baird, editors. The River of the Mother of God. University of Wisconsin Press.
Macdonald, David W., Service, Katrina. 2007. Key Topics in Conservation Biology. Blackwell Publishing, Oxford.
Schmidt, Martin H. Tscharntke, Teja. 2005. The role of perennial habitats for Central European farmland spiders. Agriculture, Ecosystems and Environment 105: 235–242
Shannon, D., Sen, A.M., Johnson, D.B. 2002. A comparative study of the microbiology of soils managed under organic and conventional regimes. Soil Use and Management 18: 274–283
Zhang, Wei., Rickets, Taylor H., Kremen, Claire., Carney, Karen., Swinton, Scott M. 2007. Ecosystem services and dis-services to agriculture. Ecological Economics 64: 253–260

[Macdonald-1] Macdonald, Key Topics in Conservation Biology, Chapter 16

[2] 1.^ Jackson et al., The Farm as Natural Habitat, Introduction

[3] 4. Jackson et al., The Farm as Natural Habitat, Ch. 10

[4] 5.^ Benton et al., 182

[FAO-5] "The future of agriculture depends on biodiversity". www.fao.org. Retrieved 2018-12-28.

[6] 7.^ Macdonald et al., Key Topics in Conservation Biology, Ch 4

[7] 8. Jackson et al., The Farm as Natural Habitat, Ch. 10

[8] 6.^ Benton et al., 183–184

[1]

vteLand use
General	Degradation Development/Conversion Planning Conflict Land management Sustainable land management Landscaping Integrated landscape management Land grabbing Land consumption Land loss Habitat loss Illegal construction Land reclamation Land rehabilitation Landscape ecology Rangeland management Environmental planning Leopold matrix Watertable control Developed environments Built-up area
Property	Property Subdivision (land) Real estate developer Land development bank Land (economics) Customary land
Related fields	Soil Soil science Soil compaction Soil pollution Overpopulation Pollution Deforestation Urban planning Infrastructure Urban renewal Agriculture Permaculture Drainage system (agriculture) Sustainable agriculture Land change modeling
Categories: Land use

Biodiversity in agriculture

Contents

Background[edit]

See also[edit]

Notes[edit]

References[edit]