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Intercropping

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Intercropping is a multiple cropping practice that involves the cultivation of two or more crops simultaneously on the same field, a form of polyculture.[1][2] The most common goal of intercropping is to produce a greater yield on a given piece of land by making use of resources or ecological processes that would otherwise not be utilized by a single crop.

Methods

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The degree of spatial and temporal overlap in the two crops can vary somewhat, but both requirements must be met for a cropping system to be an intercrop. Numerous types of intercropping, all of which vary the temporal and spatial mixture to some degree, have been identified.[3][4]

Mixed intercropping

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Mixed intercropping consists of multiple crops freely mixed in the available space. In the 21st century, it remains a common practice in Ethiopia, Eritrea, Georgia, and a few other places. Freely mixed intercropping has been practiced for thousands of years. In medieval England, farmers mixed oat and barley, which they called dredge, or dredge corn, to make livestock feed. French peasants similarly ground wheat and rye together to make pain de méteil, or bread of mixed grains. Ease of harvesting and buyer preferences led later farmers to plant single-species fields instead.[5]

Row crops

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A row crop is a crop that can be planted in rows wide enough to allow it to be tilled or otherwise cultivated by agricultural machinery, machinery tailored for the seasonal activities of row crops. Such crops are sown by drilling or transplanting rather than broadcasting. They are often grown in market gardening (truck farming) contexts or in kitchen gardens. Growing row crops first started in Ancient China in the 6th century BC.[citation needed]

Temporal

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Temporal intercropping uses the practice of sowing a fast-growing crop with a slow-growing crop, so that the fast-growing crop is harvested before the slow-growing crop starts to mature.

Relay

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Further temporal separation is found in relay cropping, where the second crop is sown during the growth, often near the onset of reproductive development or fruiting, of the first crop, so that the first crop is harvested to make room for the full development of the second.

Crop rotation is a related practice but is not a form of intercropping, as the different crops are grown in separate growing seasons rather than in a single season.

Potential benefits

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Resource partitioning

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Careful planning is required, taking into account the soil, climate, crops, and varieties. It is particularly important not to have crops competing with each other for physical space, nutrients, water, or sunlight. Examples of intercropping strategies are planting a deep-rooted crop with a shallow-rooted crop, or planting a tall crop with a shorter crop that requires partial shade. Inga alley cropping has been proposed as an alternative to the ecological destruction of slash-and-burn farming.[6]

When crops are carefully selected, other agronomic benefits are also achieved.[7][8][9]

Mutualism

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Planting two crops in close proximity can especially be beneficial when the two plants interact in a way that increases one or both of the plant's fitness (and therefore yield). For example, plants that are prone to tip over in wind or heavy rain (lodging-prone plants), may be given structural support by their companion crop.[10] Climbing plants such as black pepper can also benefit from structural support. Some plants are used to suppress weeds or provide nutrients.[11] Delicate or light-sensitive plants may be given shade or protection, or otherwise wasted space can be utilized. An example is the tropical multi-tier system where coconut occupies the upper tier, banana the middle tier, and pineapple, ginger, or leguminous fodder, medicinal or aromatic plants occupy the lowest tier.

Intercropping of compatible plants can also encourage biodiversity, McDaniel et al. 2014 and Lori et al. 2017 finding a legume intercrop to increase soil diversity,[12] or by providing a habitat for a variety of insects and soil organisms that would not be present in a single-crop environment. These organisms may provide crops valuable nutrients, such as through nitrogen fixation.[13][14][15][16]

Pest management

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There are several ways in which increasing crop diversity may help improve pest management. For example, such practices may limit outbreaks of crop pests by increasing predator biodiversity.[17] Additionally, reducing the homogeneity of the crop can potentially increase the barriers against biological dispersal of pest organisms through the crop.

There are several ways pests, typically herbivorous insects, can be controlled through intercropping:

  • Trap cropping, this involves planting a crop nearby that is more attractive for pests compared to the production crop, the pests will target this crop and not the production crop.
  • Repellant intercrops, an intercrop that has a repellent effect to certain pests can be used. This system involved the repellant crop masking the smell of the production crop in order to keep pests away from it.
  • Push-pull cropping, this is a mixture of trap cropping and repellant intercropping. An attractant crop attracts the pest and a repellant crop is also used to repel the pest away.[18]

Limitations

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Intercropping to reduce pest damage in agriculture, has been deployed with varying success. For example, while many trap crops have successfully diverted pests off of focal crops in small-scale greenhouse, garden and field experiments,[19] only a small portion of these plants have been shown to reduce pest damage at larger commercial scales.[19][20] Furthermore, increasing crop diversity through intercropping does not necessarily increase the presence of the predators of crop pests. In a systematic review of the literature, in 2008, in the studies examined, predators of pests tended to increase under crop diversification strategies in only 53 percent of studies, and crop diversification only led to increased yield in only 32% of the studies.[21] A common explanation for reported trap cropping failures, is that attractive trap plants only protect nearby plants if the insects do not move back into the main crop. In a review of 100 trap cropping examples in 2006, only 10 trap crops were classified as successful at a commercial scale,[20] and in all successful cases, trap cropping was supplemented with management practices that specifically limited insect dispersal from the trap crop back into the main crop.[20]

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See also

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References

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  1. ^ Hatcher, P E; Melander, B (19 September 2003). "Combining physical, cultural and biological methods: prospects for integrated non-chemical weed management strategies". Weed Research. 43 (5): 303–322. Bibcode:2003WeedR..43..303H. doi:10.1046/j.1365-3180.2003.00352.x. ISSN 0043-1737.
  2. ^ Abdulkareem, Basim Mohammed; Mokhtassi-Bidgoli, Ali; Ayyari, Mahdi; Keshtkar, Eshagh; Eyni-Nargeseh, Hamed (15 March 2024). "Enhancing cotton sustainability: Multi-factorial intercropping, irrigation, and weed effects on productivity, quality and physiology". Heliyon. 10 (5): e27135. Bibcode:2024Heliy..1027135A. doi:10.1016/j.heliyon.2024.e27135. ISSN 2405-8440. PMC 10912634. PMID 38444487.
  3. ^ Andrews, D. J.; Kassam, A. H. (2015). "The Importance of Multiple Cropping in Increasing World Food Supplies". Multiple Cropping. ASA Special Publications. pp. 1–10. doi:10.2134/asaspecpub27.c1. ISBN 9780891182931.
  4. ^ Lithourgidis, A.S.; Dordas, C.A.; Damalas, C.A.; Vlachostergios, D.N. (2011). "Annual intercrops: an alternative pathway for sustainable agriculture" (PDF). Australian Journal of Crop Science. 5 (4): 396–410.
  5. ^ Tarlach, Gemma (29 October 2022). "This Ancient Grain-Sowing Method Could Be Farming's Future". Wired. ISSN 1059-1028. Retrieved 31 October 2022.
  6. ^ Elkan, Daniel (21 April 2004). "Fired with ambition: Slash-and-burn farming has become a major threat to the world's rainforest". The Guardian. Retrieved 7 December 2022.
  7. ^ Abdulkareem, Basim Mohammed; Mokhtassi-Bidgoli, Ali; Ayyari, Mahdi; Keshtkar, Eshagh; Eyni-Nargeseh, Hamed (15 March 2024). "Enhancing cotton sustainability: Multi-factorial intercropping, irrigation, and weed effects on productivity, quality and physiology". Heliyon. 10 (5): e27135. Bibcode:2024Heliy..1027135A. doi:10.1016/j.heliyon.2024.e27135. ISSN 2405-8440. PMC 10912634. PMID 38444487.
  8. ^ Nawaz, Ahmad; Farooq, Muhammad; Cheema, Sardar Alam; Cheema, Zahid Ata (2014), Chauhan, Bhagirath S.; Mahajan, Gulshan (eds.), "Role of Allelopathy in Weed Management", Recent Advances in Weed Management, New York, NY: Springer, pp. 39–61, doi:10.1007/978-1-4939-1019-9_3, ISBN 978-1-4939-1019-9, retrieved 27 August 2024
  9. ^ Stomph, TjeerdJan; Dordas, Christos; Baranger, Alain; de Rijk, Joshua; Dong, Bei; Evers, Jochem; Gu, Chunfeng; Li, Long; Simon, Johan (1 January 2020), Sparks, Donald L. (ed.), "Chapter One - Designing intercrops for high yield, yield stability and efficient use of resources: Are there principles?", Advances in Agronomy, vol. 160, Academic Press, pp. 1–50, doi:10.1016/bs.agron.2019.10.002, retrieved 27 August 2024
  10. ^ Trenbath, B. R. (2015). "Plant Interactions in Mixed Crop Communities". Multiple Cropping. ASA Special Publications. pp. 129–169. doi:10.2134/asaspecpub27.c8. ISBN 9780891182931.
  11. ^ Mount Pleasant, Jane (2006). "The science behind the Three Sisters mound system: An agronomic assessment of an indigenous agricultural system in the northeast". In Staller, John E.; Tykot, Robert H.; Benz, Bruce F. (eds.). Histories of Maize: Multidisciplinary Approaches to the Prehistory, Linguistics, Biogeography, Domestication, and Evolution of Maize. Amsterdam: Academic Press. pp. 529–537. ISBN 978-1-5987-4496-5.
  12. ^ Saleem, Muhammad; Hu, Jie; Jousset, Alexandre (2 November 2019). "More Than the Sum of Its Parts: Microbiome Biodiversity as a Driver of Plant Growth and Soil Health". Annual Review of Ecology, Evolution, and Systematics. 50 (1). Annual Reviews: 145–168. doi:10.1146/annurev-ecolsys-110617-062605. ISSN 1543-592X. S2CID 199632146.
  13. ^ Wagner, S. C. (2011). "Biological Nitrogen Fixation". Nature Education Knowledge. 3 (10): 15. Archived from the original on 13 September 2018. Retrieved 1 May 2019.
  14. ^ Wang, Qi; Yang, Shengming (2017). "Host-secreted antimicrobial peptide enforces symbiotic selectivity in Medicago truncatula". PNAS. 114 (26): 6854–6859. Bibcode:2017PNAS..114.6854W. doi:10.1073/pnas.1700715114. PMC 5495241. PMID 28607058.
  15. ^ Postgate, J. (1998). Nitrogen Fixation. Cambridge University Press. Chapter 1: The nitrogen cycle; Chapter 3: Physiology; Chapter 4: The free-living microbes.
  16. ^ Smil, Vaclav (2000). Cycles of Life. Scientific American Library. Chapter: Reactive nitrogen in the biosphere. ISBN 978-0716760399.
  17. ^ Miguel Angel Altieri; Clara Ines Nicholls (2004). Biodiversity and Pest Management in Agroecosystems, Second Edition. Psychology Press. ISBN 9781560229230.
  18. ^ "Controlling Pests with Plants: The power of intercropping". UVM Food Feed. 9 January 2014. Retrieved 1 December 2016.
  19. ^ a b Shelton, A.M.; Badenes-Perez, F.R. (6 December 2005). "Concepts and applications of trap cropping in pest management". Annual Review of Entomology. 51 (1): 285–308. doi:10.1146/annurev.ento.51.110104.150959. ISSN 0066-4170. PMID 16332213.
  20. ^ a b c Holden, Matthew H.; Ellner, Stephen P.; Lee, Doo-Hyung; Nyrop, Jan P.; Sanderson, John P. (1 June 2012). "Designing an effective trap cropping strategy: the effects of attraction, retention and plant spatial distribution". Journal of Applied Ecology. 49 (3): 715–722. Bibcode:2012JApEc..49..715H. doi:10.1111/j.1365-2664.2012.02137.x. ISSN 1365-2664.
  21. ^ Poveda, Katja; Gómez, María Isabel; Martínez, Eliana (1 December 2008). "Diversification practices: their effect on pest regulation and production". Revista Colombiana de Entomología. 34 (2): 131–144. doi:10.25100/socolen.v34i2.9269. S2CID 55888993.
  22. ^ Improving nutrition through home gardening, Home Garden Technology Leaflet 13: Multilayer cropping, FAO, 2001
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