Climatic Change

, Volume 140, Issue 1, pp 33–45 | Cite as

The adaptation and mitigation potential of traditional agriculture in a changing climate

  • Miguel A. AltieriEmail author
  • Clara I. Nicholls


The threat of global climate change has caused concern among scientists because crop production could be severely affected by changes in key climatic variables that could compromise food security both globally and locally. Although it is true that extreme climatic events can severely impact small farmers, available data is just a gross approximation at understanding the heterogeneity of small scale agriculture ignoring the myriad of strategies that thousands of traditional farmers have used and still use to deal with climatic variability. Scientists have now realized that many small farmers cope with and even prepare for climate change, minimizing crop failure through a series of agroecological practices. Observations of agricultural performance after extreme climatic events in the last two decades have revealed that resiliency to climate disasters is closely linked to the high level of on-farm biodiversity, a typical feature of traditional farming systems.

Based on this evidence, various experts have suggested that rescuing traditional management systems combined with the use of agroecologically based management strategies may represent the only viable and robust path to increase the productivity, sustainability and resilience of peasant-based agricultural production under predicted climate scenarios. In this paper we explore a number of ways in which three key traditional agroecological strategies (biodiversification, soil management and water harvesting) can be implemented in the design and management of agroecosystems allowing farmers to adopt a strategy that both increases resilience and provides economic benefits, including mitigation of global warming.


Soil Organic Carbon Agroforestry System Small Farmer Traditional Agriculture Extreme Climatic Event 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Supplementary material

10584_2013_909_MOESM1_ESM.pdf (91 kb)
ESM 1 (PDF 90 kb)
10584_2013_909_MOESM2_ESM.pdf (77 kb)
ESM 2 (PDF 77 kb)
10584_2013_909_MOESM3_ESM.pdf (88 kb)
ESM 3 (PDF 87 kb)


  1. Adger WM (2000) Social and ecological resilience: are they related? Prog Hum Geogr 24:347–364CrossRefGoogle Scholar
  2. Albrecht A, Kandji ST (2003) Carbon sequestration in tropical agroforestry systems. Agric Ecosyst Environ 99:15–27Google Scholar
  3. Altieri MA (2002) Agroecology: the science of natural resource management for poor farmers in marginal environments. Agric Ecosyst Environ 93:1–24CrossRefGoogle Scholar
  4. Altieri MA (2004) Linking ecologists and traditional farmers in the search for sustainable agriculture. Front Ecol Environ 2:35–42CrossRefGoogle Scholar
  5. Altieri MA, Koohafkan P (2008) Enduring farms: climate change, smallholders and traditional farming communities. Environment and Development Series 6. Malaysia: Third World NetworkGoogle Scholar
  6. Altieri MA, Toledo VM (2005) Natural resource management among small scale farmers in semi-arid lands: building on traditional knowledge and agroecology. Annals of Arid Zone 44:365–385Google Scholar
  7. Altieri MA, Toledo VM (2011) The agroecological revolution in Latin America: rescuing nature, ensuring food sovereignity and empowering peasants. J Peasant Stud 38:587–612CrossRefGoogle Scholar
  8. Armillas P (1971) Gardens on swamps. Science 174:653–656CrossRefGoogle Scholar
  9. Barrow CJ (1999) Alternative irrigation: the promise of runoff agriculture. Earthscan Publications, Ltd, LondonGoogle Scholar
  10. Boers TM, Ben-Asher J (1982) A review of rainwater harvesting. Agric Wafer Manag 5:145–158CrossRefGoogle Scholar
  11. Campesina V (2010) Sustainable peasant and small family farm agriculture can feed the world. Via Campesina Views, JakartaGoogle Scholar
  12. Critchley WRS (1989) Building on a tradition of rainwater harvesting. Appropr Technol 16(2):10–12Google Scholar
  13. Critchley WRS, Reij C, Willcocks TJ (2004) Indigenous soil and water conservation: a review of the state of knowledge and prospects for building on traditions. Land Degradation and Rehabilitations 5:293–314CrossRefGoogle Scholar
  14. De Schutter O (2010) Report submitted by the Special Rapporteur on the right to food. UN General Assembly. Human Rights Council Sixteenth Session, Agenda item 3 A/HRC/16/49Google Scholar
  15. Denevan WM (1995) Prehistoric agricultural methods as models for sustainability. Adv Plant Pathol 11:21–43CrossRefGoogle Scholar
  16. Diaz-Zorita M, Buschiazzo DE, Peineman N (1999) Soil organic matter and wheat productivity in the Semiarid Argentine Pampas. Agron J 91:276–279CrossRefGoogle Scholar
  17. Erickson CL, Chandler KL (1989) Raised fields and sustainable agriculture in Lake Titicaca Basin of Peru. In: Browder JO (ed) Fragile lands of Latin America. Westview Press, Boulder, pp 230–243Google Scholar
  18. ETC Group (2009) Who will feed us? Questions for the food and climate crisis. ETC Group Comunique #102Google Scholar
  19. Gliessman SR, Garcia RE, Amador AM (1981) The ecological basis for the application of traditional agricultural technology in the management of tropical agroecosystems. Agroecosyst 7:173–185Google Scholar
  20. Hart TGB, Vorster HJ (2007) African Indigenous Knowledge Systems in Agricultural Production. Pretoria: Department of Science and Technology: National Indigenous Knowledge OfficeGoogle Scholar
  21. Holt-Giménez E (2002) Measuring farmers’ agroecological resistance after Hurricane Mitch in Nicaragua: a case study in participatory, sustainable land management impact monitoring. Agric Ecosyst Environ 93:87–105CrossRefGoogle Scholar
  22. IAASTD (International Assessment of Agricultural Knowledge, Science and Technology for Development) (2009) Agriculture at a Crossroads. In: International Assessment of Agricultural Knowledge, Science and Technology for Development Global Report, Island Press, Washington, D.C.Google Scholar
  23. Jones PG, Thornton PK (2003) The potential impacts of climate change on maize production in Africa and Latin America in 2055. Glob Environ Chang 13:51–59CrossRefGoogle Scholar
  24. Koohafkan P, Altieri MA (2010) Globally important agricultural heritage systems: a legacy for the future. UN-FAO, RomeGoogle Scholar
  25. Lin BB, Perfecto I, Vandermeer J (2008) Synergies between agricultural intensification and climate change could create surprising vulnerabilities for crops. BioScience 58:847–854CrossRefGoogle Scholar
  26. Magdoff F, Weil R (2004) Soil organic matter management strategies. In: Magdoff F, Weil R (eds) Soil organic matter in sustainable agriculture. CRC Press, Boca RatonCrossRefGoogle Scholar
  27. Montagnini F, Nair PKR (2004) Carbon sequestration: an underexploited environmental benefit of agroforestry systems. Agrofor Syst 61:281–295Google Scholar
  28. Mutuo PK, Cadisch G, Albrecht A, Palm CA, Verchot L (2005) Potential of agroforestry for carbon sequestration and mitigation of greenhouse gas emissions from soils in the tropics. Nutr Cycl Agroecosyst 71:43–54CrossRefGoogle Scholar
  29. Nair PK, Kumat BM, Nair VD (2009) Agroforestry as a strategy for carbon sequestration. J Plant Nutr Soil Sci 72:10–23CrossRefGoogle Scholar
  30. Niggli U, Fliessbach A, Hepperly P, Scialabba N (2008) Low greenhouse gas agriculture: mitigation and adaptation potential of sustainable farming systems. FAO, RomeGoogle Scholar
  31. Perfecto I, Vandermeer J, Wright A (2009) Nature’s matrix: linking agriculture, conservation and food sovereignty. Earthscan, LondonGoogle Scholar
  32. Philpott SM, Lin BB, Jha S, Brines SJ (2009) A multiscale assessment of hurricane impacts on agricultural landscapes based on land use and topographic features. Agric Ecosyst Environ 128:12–20CrossRefGoogle Scholar
  33. Reij C, Scoones I, Toulmin C (1996) Sustaining the soil: indigenous soil and water conservation in Africa. Earthscan, LondonGoogle Scholar
  34. Rojas Rabiela T (1993) La agricultura chinampera: compilacion historica. Universidad Autonoma de Chapingo, MexicoGoogle Scholar
  35. Rosenzweig C, Hillel D (2008) Climate change and the global harvest: impacts of El Nino and other oscillations on agroecosystems. Oxford University Press, New YorkGoogle Scholar
  36. Rosset PM, Machín-Sosa B, Roque-Jaime AM, Avila-Lozano DR (2011) The Campesino-to-Campesino Agroecology movement of ANAP in Cuba. J Peasant Stud 38(1):161–191CrossRefGoogle Scholar
  37. Sombroek W, Ruivo ML, Fearnside PM, Glaser B, Lehmann J (2003) Amazonian dark earths as carbon stores and sinks. In: Lehmann J, Kern D, German LA, McCann JM, Martins GC, Moreira A (eds) Amazonian dark earths: origin, properties. Management. Kluwer Academic Publishers, Netherlands, pp 125–139Google Scholar
  38. Stigter C, Dawei Z, Onyewotu L, Xurong M (2005) Using traditional methods and indigenous technologies for coping with climate variability. Clim Chang 70:255–271CrossRefGoogle Scholar
  39. Tester M, Langridge P (2010) Breeding technologies to increase crop production in a changing world. Science 327:818–822CrossRefGoogle Scholar
  40. Toledo VM, Barrera-Bassols N (2008) La Memoria Biocultural: la importancia ecologica de las sabidurıas tradicionales. ICARIA Editorial, BarcelonaGoogle Scholar
  41. Tompkins EL, Adger WN (2004) Does Adaptive Management of Natural Resources Enhance Resilience to Climate Change? Ecology and Society 9(2): 10. [online] URL:
  42. Tscharntke T, Klein AM, Kruess A, Steffan-Dewenter I, Thies C (2005) Landscape perspectives on agricultural intensification and biodiversity: ecosystem service management. Ecol Lett 8:857–874CrossRefGoogle Scholar
  43. Vietmeyer N (1984) The lost crops of the Incas. Ceres 99:37–40Google Scholar
  44. Wilken GC (1987) Good farmers: traditional agricultural resource management in Mexico and Central America. University of California Press, BerkeleyGoogle Scholar

Copyright information

© Springer Science+Business Media Dordrecht 2013

Authors and Affiliations

  1. 1.Dept of Environmental Science, Policy, & ManagementUniversity of California, BerkeleyBerkeleyUSA
  2. 2.Department of International & Area StudiesUniversity of California, BerkeleyBerkeleyUSA

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