Abstract
Natural ecosystems, whose components are the results of natural selection, are sustainable; most are productive, responsive to pests, and retentive of nutrients. Thus, they are appropriate models on which to base the design of new systems of land use. Abiotic and biotic stressors are related non-linearly; the nadir of total stress being mid-way along a gradient of environmental harshness. Superimposing the stress functions on Holdridge's life zone chart yields four broad categories of environments for agriculture: climates where annual rainfall is similar to potential evapotranspiration, plus three other categories that are either too cold, too arid, or too wet. Extremely cold lands have no potential for agriculture. Lands that are arid or infertile can be used successfully, although the cost of compensating for environmental limitations increases exponentially with increasing abiotic stress. Grazing animals (which act as trophic buffers between people and environment) have proven successful in dry and infertile environments. The humid tropical lowlands epitomise environments of low abiotic stress but overwhelming biotic intricacy. Here it pays to imitate natural systems rather than struggle to impose simplicity on ecosystems that are inherently complex. The keys to success are to (i) channel productivity into outputs of nutritional and economic importance, (ii) maintain adequate diversity to compensate for losses in a system simple enough to be horticulturally manageable, (iii) manage plants and herbivores to facilitate associational resistance and not associational susceptibility, and (iv) use perennial plants to maintain soil fertility, guard against erosion, and make full use of resources.
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References
Alvarez FN and Banal N (1984) El huerto casero: manual de agricultura orgánica. Editorial Claridad, Maunabo, Puerto Rico
Berish CW (1982) Root biomass and surface area in three successional tropical forests. Canadian Journal of Forest Research 12: 699–704
Berish CW and Ewel JJ (1988) Root development in simple and complex tropical successional ecosystems. Plant and Soil 106: 73–84
Blanton CM and Ewel JJ (1985) Leaf-cutting ant herbivory in successional and agricultural tropical ecosystems. Ecology 66: 861–869
Breman H and de Wit CT (1983) Rangeland productivity and exploitation in the Sahel. Science 221: 1341–1347
Brown BJ and Ewel JJ (1987) Herbivory in complex and simple tropical successional ecosystems. Ecology 68: 108–116
Brown LR (1970) Seeds of Change: The Green Revolution and Development in the 1970s. Praeger, New York, USA
Carr AF (1964) Ulendo: Travels of a Naturalist In and Out of Africa. Knopf, New York, USA
Coughenour MB, Ellis JE, Swift DM, Coppock DL, Galvin K, McCabe JT and Hart TC (1985) Energy extraction and use in a nomadic pastoral ecosystem. Science 230: 619–625
Denevan WM, Treacy JM, Alcorn JB, Padoch C, Denslow J and Paitan SF (1984) Indigenous agroforestry in the Peruvian Amazon: Bora Indian management of swidden fallows. Interciencia 9: 346–357
Ewel J (1986) Designing agricultural ecosystems for the humid tropics. Annual Review of Ecology and Systematics 17: 245–271
Ewel J, Benedict F, Berish C, Brown B, Gliessman S, Amador M, Bermúdez R, Martínez A, Miranda R and Price N (1982) Leaf area, light transmission, roots and leaf damage in nine tropical plant communities. Agro-Ecosystems 7: 305–326
Ewel J, Berish C, Brown B, Price N and Raich J (1981) Slash and burn impacts on a Costa Rican wet forest site. Ecology 62: 816–829
Ewel JJ and Bigelow SW (1996) Plant life-forms and tropical ecosystem functioning. Ecological Studies 122: 101–126
Ewel JJ, Mazzarino MJ and Berish CW (1991) Tropical soil fertility changes under monocultures and successional communities of different structure. Ecological Applications 1: 289–302
Falanruw MVC (1994) Food production and ecosystem management on Yap. ISLA: A Journal of Micronesian Studies 2: 5–22
Fernandes ECM, Oktingati A and Maghembe J (1984) The Chagga homegardens: a multistoried agroforestry cropping system on Mt. Kilimanjaro (Northern Tanzania). Agroforestry Systems 2: 73–86
Harris M (1965) The myth of the sacred cow. In: Leeds A and Vayda AP (eds) Man, Culture, and Animals, pp 217–228. AAAS, Washington DC
Harris M (1972) How green the revolution. Natural History 81: 28–30
Harris M (1973) The withering green revolution. Natural History 82: 20–23
Hatfield CB (1997) Oil back on the global agenda. Nature 387: 121
Holdridge LR (1947) Determination of world plant formations from simple climatic data. Science 105: 367–368
Holdridge LR (1967) Life Zone Ecology. Tropical Science Center, San José, Costa Rica (Revised edition)
Holdridge LR, Grenke WC, Hatheway WH, Liang T and Tosi JA, Jr (1971) Forest Environments in Tropical Life Zones: A Pilot Study. Pergamon Press, New York, USA
Hunter JR (1959) The Climatic Limits of Cacao, Coffee, and Rubber. Inter-American Institute of Agricultural Sciences #16, Turrialba, Costa Rica
Jackson LL and Dewald CL (1994) Predicting evolutionary consequences of greater reproductive effort in Tripsacum dactyloides, a perennial grass. Ecology 75: 627–641
Jackson W (1985) New Roots for Agriculture, 2nd ed. University of Nebraska Press, Lincoln, Nebraska, USA
Manner HI (1981) Ecological succession in new and old swiddens of montane Papua New Guinea. Human Ecology 9: 359–377
Michon G (1997) The agroforest alternative to Imperata grasslands: when smallholder agriculture and forestry reach sustainability. Agroforestry Systems 36: 105–120
Mitscherlich EA (1923) Bodenkunde für Land-und Forstwirte. Paul Parey, Berlin
National Research Council (U.S.) (1993) Sustainable Agriculture and the Environment in the Humid Tropics. National Academy of Sciences, Washington, DC, USA
Nulsen RA, Bligh KJ, Baxter IN, Solin EJ and Imrie DH (1986) The fate of rainfall in a mallee and heath vegetated catchment in southern Western Australia. Australian Journal of Ecology 11: 361–371
Odend'hal S (1972) Energetics of Indian cattle in their environment. Human Ecology 1: 3–22
Odum HT (1967) Energetics of world food production. In: The world food problem. A report of the President's Science Advisory Committee, Volume 3: Report of the Panel on the World Food Supply, pp 55–94. US Government Printing Office, Washington, DC
Paddock WC (1970) How green is the green revolution? BioScience 20: 897–902
Pinedo-Vásquez M and Padoch C (1996) Managing forest remnants and forest gardens in Peru and Indonesia. In: Schelhas J and Greenberg R (eds) Forest Patches in Tropical Landscapes, pp 327–342. Island Press, Washington, DC
Post WM, Emanuel WR, Zinke PJ and Stangenberger AG (1982) Soil carbon pools and world life zones. Nature 298: 156–159
Post WM, Pastor J, Zinke PJ and Stangenberger AG (1985) Global patterns of soil nitrogen storage. Nature 317: 613–616
Raich JW, Ewel JJ and Olivera M (1985) Soil-CO2 efflux in simple and diverse ecosystems on a volcanic soil in Costa Rica. Turrialba 35: 33–42
Russell AE and Ewel JJ (1985) Leaching from a tropical andept during big storms: a comparison of three methods. Soil Science 139: 181–189
Sanchez PA, Bandy DE, Villachica JH and Nicholaides JJ (1982) Amazon Basin soils: management for continuous crop production. Science 216: 821–827
Sanchez PA and Benites JR (1987) Low-input cropping for acid soils of the humid tropics. Science 238: 1521–1527
Sanchez PA and Salinas JG (1981) Low-input technology for managing oxisols and ultisols in tropical America. Advances in Agronomy 34: 279–406
Seavoy RE (1973) The shading cycle in shifting cultivation. Annals of the Association of American Geographers 63: 522–528
Soule JD and Piper JK (1992) Farming in Nature's Image. Island Press, Washington, DC
Specht RL (1957) Dark island heath (Ninety Mile Plain, South Australia), iv. Soil moisture patterns produced by rainfall interception and stemflow. Australian Journal of Botany 5: 137–150
Tosi Jr. JA (1964) Climatic control of terrestrial ecosystems: a report on the Holdridge model. Economic Geography 40: 173–181
Tosi Jr. JA and Voertman RF (1964) Some environmental factors in the economic development of the tropics. Economic Geography 40: 189–205
Wadsworth FW (1998) Forest Production for Tropical America: USDA Forest Service Agricultural Handbook 710. USDA Forest Service, Government Printing Office, Washington, DC
Wilkes HG and Wilkes S (1972) The green revolution. Environment 14: 32–39
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Ewel, J.J. Natural systems as models for the design of sustainable systems of land use. Agroforestry Systems 45, 1–21 (1999). https://doi.org/10.1023/A:1006219721151
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DOI: https://doi.org/10.1023/A:1006219721151