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1.Is ecological agriculture productive?
2.Small farms as a planetary ecological asset

QUOTE: "The poor and hungry need low-cost, readily available technologies and practices to increase food production." - editorial in New Scientist

EXTRACT: In developing countries, ecological agriculture practices can greatly increase productivity, particularly if the existing system is low-input, which is largely the case for Africa.
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1.Is ecological agriculture productive?
TWN, 19 December 2008
http://www.twnside.org.sg/title2/susagri/susagri064.htm

A key question that is often asked about ecological agriculture, including organic agriculture, is whether it can be productive enough to meet the world's food needs. While many agree that ecological agriculture is desirable from an environmental and social point of view, there remain fears that ecological and organic agriculture produce low yields.

Please find below a paper that summarizes some of the available evidence to demystify the productivity debate and demonstrate that ecological agriculture is indeed productive, especially so in developing countries.

With best wishes,

Third World Network
131 Jalan Macalister
10400 Penang
Malaysia
Email: This email address is being protected from spambots. You need JavaScript enabled to view it.
Websites: www.twnside.org.sg, www.biosafety-info.net

Is Ecological Agriculture Productive?
By Lim Li Ching, Researcher, Third World Network (November 2008)

Introduction

A key question that is often asked about ecological agriculture, including organic agriculture, is whether it can be productive enough to meet the world’s food needs. While many agree that ecological agriculture is desirable from an environmental and social point of view, there remain fears that ecological and organic agriculture produce low yields.

This short paper will summarise some of the available evidence to demystify the productivity debate and demonstrate that ecological agriculture is indeed productive.

In general, yields from ecological agriculture can be broadly comparable to conventional yields in developed countries. In developing countries, ecological agriculture practices can greatly increase productivity, particularly if the existing system is low-input, which is largely the case for Africa. This paper will focus mainly on evidence from developing countries.

Evidence from global modelling

A recent study examined a global dataset of 293 examples and estimated the average yield ratio (organic : non-organic) of different food categories for the developed and developing world  (Badgley et al., 2007). For most of the food categories examined, they found that the average yield ratio was slightly less than 1.0 for studies in the developed world, but more than 1.0 for studies in developing countries.

On average, in developed countries, organic systems produce 92% of the yield produced by conventional agriculture. In developing countries, however, organic systems produce 80% more than conventional farms.

With the average yield ratios, the researchers then modeled the global food supply that could be grown organically on the current agricultural land base. They found that organic methods could hypothetically produce enough food on a global per capita basis to sustain the current human population, and potentially an even larger population, without putting more farmland into production.

Moreover, contrary to fears that there are insufficient quantities of organically acceptable fertilizers, the data suggest that leguminous cover crops could fix enough nitrogen to replace the amount of synthetic fertilizer currently in use.

This model suggests that organic agriculture could potentially provide enough food globally, but without the negative environmental impacts of conventional agriculture.

Evidence from reviews of ecological agriculture projects

In a review of 286 projects in 57 countries, farmers were found to have increased agricultural productivity by an average of 79%, by adopting “resource-conserving” or ecological agriculture (Pretty et al., 2006).

A variety of resource conserving technologies and practices were used, including integrated pest management, integrated nutrient management, conservation tillage, agroforestry, water harvesting in dryland areas, and livestock and aquaculture integration into farming systems. These practices not only increased yields, but also reduced adverse effects on the environment and contributed to important environmental goods and services (e.g., climate change mitigation), as evidenced by increased water use efficiency and carbon sequestration, and reduced pesticide use.

The work built on earlier research, which assessed 208 sustainable agriculture projects. The earlier research found that for 89 projects for which there was reliable yield data, farmers had, by adopting sustainable agriculture practices, achieved substantial increases in per hectare food production - the yield increases were 50-100% for rain-fed crops, though considerably greater in a number of cases, and 5-10% for irrigated crops (Pretty and Hine, 2001).

Disaggregated data show:

    * Average food production per household rose by 1.7 tonnes per year (up by 73%) for 4.42 million small farmers growing cereals and roots on 3.6 million hectares.
    * Increase in food production was 17 tonnes per year (up 150%) for 146,000 farmers on 542,000 hectares cultivating roots (potato, sweet potato, cassava).
    * Total production rose by 150 tonnes per household (up by 46%) for the larger farms in Latin America (average size 90 hectares).

The database on agricultural sustainability (comprising the 286 projects) was reanalyzed to produce a summary of the impacts of organic and near-organic projects on agricultural productivity in Africa (Hine and Pretty, 2008). The average crop yield increase was even higher for these projects than the global average (79%): 116% increase for all African projects and 128% increase for the projects in East Africa.

For Kenyan projects, the increase in yield was 179%, for Tanzanian projects 67% and for Ugandan projects 54%. Moreover, all case studies that focused on food production in this research where data have been reported, showed increases in per hectare productivity of food crops, which challenges the popular myth that organic agriculture cannot increase agricultural productivity.

Evidence from specific ecological agriculture interventions

Data from the Tigray Project in the Tigray Region in Ethiopia, where a project on ecological agriculture has been carried out since 1996, concretely demonstrate the benefits of compost on productivity. Preliminary data collected in 1998 had already shown that using compost gave similar yield increases as chemical fertilizers. Data collected in 2002, 2003 and 2004 showed that, on average, composted fields gave higher yields, sometimes double, than those treated with chemical fertilizers (Araya and Edwards, 2006).

In a new paper written for the UN Food and Agriculture Organization (FAO), statistical analysis on a larger data set over the years 2000 to 2006 inclusive confirms that compost use in Tigray has increased yields in all the crops analysed (Edwards et al., 2008). In total, data was collected from 974 fields from 19 communities. Grain and straw yield data were obtained for barley, durum wheat, finger millet, hanfets (a mixture of barley and durum wheat), maize, sorghum, teff, faba bean and field pea.

Except for field pea, the compost generally doubled the grain yield when compared to each respective check (crops grown without any inputs). (For field pea, the increase in yield was approximately 28%.) The difference was significant (95% confidence limit). The application of compost also increased straw yield compared to the check, but not to the same extent as it increased grain yield.

The use of compost also gave higher yields than the use of chemical fertilizer, though differences in the yields from compost and from chemical fertilizer were not as great as the differences between the use of compost and the check. For sorghum and faba bean the yields from the use of compost and chemical fertilizer were similar. But the yield difference for all the other crops was greater with that from the compost treatment being always higher than that from the use of chemical fertilizer. The results also showed that compost not only increases the overall biomass yield, but also increases the proportion of the grain to straw in the yield.

Since 1998, the Bureau of Agriculture and Rural Development of Tigray Region has adopted the making of compost as part of its extension package and by 2007 at least 25% of the farmers are making and using compost. A reflection of the success of this approach is that between 2003 and 2006, grain yield for the Region almost doubled from 714 to 1,354 thousand tonnes. Since 1998, there has also been a steady decrease in the use of chemical fertilizer from 13.7 to 8.2 thousand tonnes.

There are many other specific examples of increased yields following the application of ecological agriculture practices, some of which are summarized below (Hine and Pretty, 2008; Parrott and Marsden, 2002; Pretty and Hine, 2001; Scialabba and Hattam, 2002).

In Africa:

    * Soil and water conservation in the drylands of Burkina Faso and Niger have transformed formerly degraded lands. The average family has shifted from being in cereal deficit of 644 kg per year (equivalent to 6.5 months of food shortage) to producing an annual surplus of 153 kg.
    * In Ethiopia, some 12,500 households have adopted sustainable agriculture, resulting in a 60% increase in crop yields.
    * In Tigray, Ethiopia, yields of crops from composted plots were 3-5 times higher than those treated only with chemicals.
    * Projects in Senegal promoted stall-fed livestock, composting systems, green manures, water harvesting systems and rock phosphate. Yields of millet and peanuts increased dramatically by 75-195% and 75-165% respectively.
    * In Kenya, 500 farmers on some 1000 hectares have seen maize yields improve from about 2 to 4 t/ha following the application of soil conservation, soil fertility and organic agriculture methods.
    * A range of biological pest management methods together with legumes, cover crops and green manures for soil fertility improvement resulted in a doubling of beans and groundnut yields from 300 to 600 kg/ha in western Kenya.
    * In eastern and central Kenya, smallholder farmers have been trained in natural soil fertility management; integrated environmentally friendly weed, pest and disease protection; on-farm soil and water conservation techniques; and farm level seed conservation, with a resulting 50% increase in productivity and 40% increase in income.
    * More than 1000 farmers in low soil fertility areas in the North Rift and western regions of Kenya increased maize yields to 3,414 kg/ha (71% increase in productivity) and bean yields to 258 kg/ha (158% increase in productivity) as compared to traditional agriculture, by incorporating soil fertility management, crop diversification and improved crop management.
    * Integration of pond fish culture into low-input farm systems with some 2000 farmers in Malawi increased vegetable yields from 2700 to 4000 kg/ha, with the fish ponds producing the equivalent of 1500 kg/ha of fish, a new source of food for households.

In Latin America:

    * 45,000 families in Honduras and Guatemala have increased crop yields from 400-600 kg/ha to 2000-2500 kg/ha using green manures, cover crops, contour grass strips, in-row tillage, rock bunds and animal manures.
    * The states of Santa Caterina, Paraná and Rio Grande do Sol in southern Brazil have focused on soil and water conservation using contour grass barriers, contour ploughing and green manures. Maize yields have risen from 3 to 5 tonnes/ha and soybeans from 2.8 to 4.7 tonnes/ha.
    * The high mountain regions of Peru, Bolivia and Ecuador are some of the most difficult areas in the world for growing crops. Despite this, farmers have increased potato yields by three fold, particularly by using green manures to enrich the soil. Using these methods, some 2000 farmers in Bolivia have improved potato production from about 4000 kg/ha to 10-15000 kg/ha.
    * In Brazil, use of green manures and cover crops increased maize yields by between 20-250%.
    * In Peru, restoration of traditional Incan terracing led to increases of 150% for upland crops.
    * In Honduras, soil conservation practices and organic fertilisers have tripled or quadrupled yields.
    * In Cuba, there are more than 7000 organic urban gardens and productivity has grown from 1.5 kg/m2 to nearly 20 kg/m2.

In Asia:

    * Participatory irrigation management in Philippines has increased rice yields by about 20%.
    * Yield increases of 175% were reported from farms in Nepal adopting agro-ecological practices.
    * In Pakistan, yields of mango and citrus fruits increased by 150-200% after adopting organic agriculture techniques such as mulching, no till production, composting and planting the fruit trees in double dug beds.

Conclusion

It is clear that ecological agriculture is productive and has the potential to meet food security needs, particularly in the African context. The International Assessment of Agricultural Knowledge, Science and Technology for Development concurs that an increase and strengthening of agricultural knowledge, science and technology toward agroecological sciences will contribute to addressing environmental issues while maintaining and increasing productivity (IAASTD, 2008). Moreover, ecological agricultural approaches allow farmers to improve local food production with low-cost, readily available technologies and inputs, without causing environmental damage.

References

Araya, H. and Edwards, S. 2006. The Tigray experience: A success story in sustainable agriculture. Third World Network Environment and Development Series 4. TWN: Penang.

Badgley, C., Moghtader, J., Quintero, E., Zakem, E., Chappell, M.J., Avilés-Vázquez, K., Samulon, A. & Perfecto, I. 2007. Renewable Agriculture and Food Systems, 22: 86-108.

Edwards, S., Asmelash A., Araya, H. and Egziabher, T.B.G. 2008. The impact of compost use on crop yields in Tigray, Ethiopia, 2000-2006 inclusive.

Hine, R. and Pretty, J. 2008. Organic agriculture and food security in Africa. United Nations Conference on Trade and Development (UNCTAD) and United Nations Environment Programme (UNEP): Geneva and New York.

IAASTD. 2008. International Assessment of Agricultural Knowledge, Science and Technology for Development. www.agassessment.org

Parrott, N. and Marsden, T. 2002. The real Green Revolution: Organic and agroecological farming in the South. Greenpeace Environment Trust: London.

Pretty, J. & Hine, R. 2001. Reducing food poverty with sustainable agriculture: a summary of new evidence. UK: University of Essex Centre for Environment and Society.

Pretty, J.N., Noble, A.D., Bossio, D., Dixon, J., Hine, R.E., Penning de Vries, F.W.T. & Morison, J.I.L. 2006. Resource-conserving agriculture increases yields in developing countries. Environmental Science and Technology (Policy Analysis)  40(4): 1114-1119.

Scialabba, N.E-H. and Hattam, C. (eds). 2002. Organic Agriculture, Environment and Food Security. Rome: FAO.
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2.Small farms as a planetary ecological asset
http://www.twnside.org.sg/title2/susagri/susagri045.htm

The paper below, by Miguel Altieri, President of the Latin American Scientific Society of Agroecology (SOCLA) and Professor of Agroecology at the University of California, Berkeley, argues that small farms are ecological assets.

Small farming systems are still prevalent in Latin America, Asia and Africa, and high levels of agrobiodiversity are salient features of such systems. Altieri highlights five important reasons (among others) why small farms should be supported, particularly given current economic conditions and climate variability:

1.  Small farmers are key for the world’s food security
2.  Small farms are more productive and resource conserving than large scale monocultures
3.  Small traditional and biodiverse farms represent models of sustainability
4.  Small farms represent a sanctuary of GMO free agrobiodiversity
5.  Small farms cool the climate

The paper can also be found at http://www.landaction.org/spip/spip.php?article315

With best wishes,



Lim Li Ching

Third World Network

131 Jalan Macalister
10400
Penang

Malaysia

Email: This email address is being protected from spambots. You need JavaScript enabled to view it.

Websites: www.twnside.org.sg, www.biosafety-info.net

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Small farms as a planetary ecological asset: Five key reasons why we should support the revitalization of small farms in the global South

Miguel A. Altieri
President, Sociedad Cientifica LatinoAmericana de Agroecologia (SOCLA)

The Via Campesina has long argued that farmers need land to produce food for their own communities and for their country and for this reason has advocated for genuine agrarian reforms to access and control land, water, agrobiodiversity, etc., which are of central importance for communities to be able to meet growing food demands.  The Via Campesina believes that in order to protect livelihoods, jobs, people's food security and health as well as the environment, food production has to remain in the hands of small scale sustainable farmers and cannot be left under the control of large agribusiness companies or supermarket chains. Only by changing the export-led, free-trade based, industrial agriculture model of large farms can the downward spiral of poverty, low wages, rural-urban migration, hunger and environmental degradation be halted. Social rural movements embrace the concept of food sovereignty as an alternative to the neo-liberal approach that puts its faith in an inequitable
international trade to solve the world’s food problem. Instead, it focuses on local autonomy, local markets, local production-consumption cycles, energy and technological sovereignty and farmer to farmer networks.

Being a global movement, the Via Campesina has recently brought their message to the North, partly to gain the support of foundations and consumers, as political pressure from a wealthier public which increasingly depends on unique food products from the South marketed via organic, fair trade, or slow food channels could marshal the sufficient political will to curb the expansion of biofuels, transgenic crops and agroexports and put an end to subsidies to industrial farming and dumping practices that hurt small farmers in the South. But can these arguments really captivate the attention and support of northern consumers and philantropists? Or is there a need to come up with a different argument, one that emphasizes that the very quality of life and food security of the populations in the North depend not only on the food products, but in the ecological services provided by small farms of the South. In fact it is herein argued that the functions performed by small farming systems
still
prevalent in Africa, Asia and Latin America, in the post peak oil era that humanity is entering, comprise an ecological asset for humankind and planetary survival. In fact, in an era of escalating fuel and food costs, climate change, environmental degradation, GMO pollution and corporate dominated food systems, small, biodiverse, agroecologically managed farms in the Global South are the only viable form of agriculture that will feed the world under the new ecological end economic scenario.

There are at last five reasons why Northern consumers should support the cause and struggle of small farmers in the South:

1. Small farmers are key for the world’s food security

While 91% of the planet’s 1,5 billion hectares of agricultural land are increasingly being devoted to agroexport crops, biofuels and transgenic soybean to feed cars and cattle, millions of small farmers in the developing world produce the majority of staple crops needed to feed the planet’s rural and urban populations. In Latin America, about 17 million peasant production units occupying close to 60.5 million hectares, or 34.5% of the total cultivated land with average farm sizes of about 1.8 hectares, produce 51% of the maize, 77% of the beans, and 61% of the potatoes for domestic consumption. Africa has approximately 33 million small farms, representing 80 percent of all farms in the region. Despite the fact that Africa now imports huge amounts of cereals, the majority of African farmers (many of them women) who are smallholders with farms below 2 hectares, produce a significant amount of basic food crops with virtually no or little use of fertilizers and improved seed. In Asia,
the
majority of more than 200 million rice farmers, few farm more than 2 ha of rice make up the bulk of the rice produced by Asian small farmers. Small increases in yields on these small farms that produce most of the world´s staple crops will have far more impact on food availability at the local and regional levels, than the doubtful increases predicted for distant and corporate controlled large monocultures managed with such high tech solutions as genetically modified seeds.

2. Small farms are more productive and resource conserving than large scale monocultures

Although the conventional wisdom is that small family farms are backward and unproductive, research shows that small farms are much more productive than large farms if total output is considered rather than yield from a single crop. Integrated farming systems in which the small-scale farmer produces grains, fruits, vegetables, fodder, and animal products out-produce yield per unit of single crops such as corn (monocultures) on large-scale farms.  A large farm may produce more corn per hectare than a small farm in which the corn is grown as part of a polyculture that also includes beans, squash, potato and fodder.  In polycultures developed by smallholders, productivity in terms of harvestable products per unit area is higher than under sole cropping with the same level of management. Yield advantages can range from 20 percent to 60 percent, because polycultures reduce of losses due to weeds, insects and diseases and make a more efficient use of the available resources of water, light
and nutrients. In overall output, the diversified farm produces much more food, even if measured in dollars. In the USA data shows that the smallest two-hectare farms produced $15,104 per hectare and netted about $2,902 per acre. The largest farms, averaging 15,581 hectares, yielded $249 per hectare and netted about $52 per hectare. Not only do small-medium sized farms exhibit higher yields than conventional farmers, but they do so with much lower negative impact on the environment. Small farms are ‘multi-functional’ more productive, more efficient, and contribute more to economic development than do large farms. Communities surrounded by populous small farms have healthier economies than do communities surrounded by depopulated large mechanized farms. Small farmers also take better care of natural resources, including reducing soil erosion and conserving biodiversity.

The inverse relationship between farm size and output can be attributed to the more efficient use of land, water, biodiversity and other agricultural resources by small farmers.  So in terms of converting inputs into outputs, society would be better off with small-scale farmers. Building strong rural economies in the Global South based on productive small scale farming will allow the people of the South to remain with their families and will help to stem the tide of out migration. And as population continues to grow and the amount of farmland and water available to each person continues to shrink, a small farm structure may become central to feeding the planet, especially when large scale agriculture devotes itself to feeding car tanks.

3. Small traditional and biodiverse farms represent models of sustainability

Despite the onslaught of industrial farming, the persistence of thousands of hectares under traditional agricultural management documents a successful indigenous agricultural strategy of adaptability and resiliency. These microcosms of traditional agriculture that have stood the test of time, and that can still be found almost untouched since 4 thousand years in the Andes, MesoAmerica, south east Asia and parts of Africa, offer promising models of sustainability as they promote biodiversity, thrive without agrochemicals, and sustain year-round yields even under marginal environmental conditions. The local knowledge accumulated during millennia and the forms of agriculture and agrobiodiversity that this wisdom has nurtured, comprise a Neolithic legacy embedded with ecological and cultural resources of fundamental value for the future of humankind.

Recent research suggests that many small farmers cope and even prepare for climate change, minimizing crop failure through increase used of drought tolerant local varieties, water harvesting, mixed cropping, opportunistic weeding, agroforestry and a series of other traditional techniques. Surveys conducted in hillsides after Hurricane Mitch in Central America showed that farmers using sustainable practices such as “mucuna” cover crops, intercropping and agroforestry suffered less “damage” than their conventional neighbors. The study spanning 360 communities and 24 departments in Nicaragua, Honduras and Guatemala showed that diversified plots had 20% to 40% more topsoil, greater soil moisture, less erosion and experienced lower economic losses than their conventional neighbors.

This points to the fact that a re-evaluation of indigenous technology can serve as a key source of information on adaptive capacity and resilient capabilities exhibited by small farms, features of strategic importance for world farmers to cope with climatic change. In addition, indigenous technologies often reflect a worldview and an understanding of our relationship to the natural world that is more realistic and more sustainable that those of our Western European heritage.

4. Small farms represent a sanctuary of GMO free agrobiodiversity

In general, traditional small scale farmers grow a wide variety of cultivars . Many of these plants are landraces grown from seed passed down from generation to generation, more genetically heterogeneous than modern cultivars and thus offering greater defenses against vulnerability and enhancing harvest security in the midst of diseases, pests, droughts and other stresses.  In a worldwide survey of crop varietal diversity on farm involving 27 crops, scientists found that considerable crop genetic diversity continues to be maintained on farm in the from of traditional crop varieties, especially of major staple crops.  In most cases, farmers maintain diversity as in insurance to meet future environmental change or social and economic needs. Many researchers have concluded that variety richness enhances productivity and reduces yield variability. For example, studies by plant pathologists provide evidence that mixing of crop species and or varieties can delay the onset of diseases by
reducing the spread of disease carrying spores, and by modifying environmental conditions so that they are less favorable to the spread of certain pathogens.  Recent research in China, where four different mixtures of rice varieties grown by farmers from fifteen different townships over 3000 hectares, suffered 44% less blast incidence and exhibited 89% greater yield than homogeneous fields without the need to use pesticides.

At issue is the possibility that traits important to indigenous farmers (resistance to drought, competitive ability, performance on intercrops, storage quality, etc) could be traded for transgenic qualities which may not be important to farmers (Jordan, 2001). Under this scenario risk could increase and farmers would lose their ability to adapt to changing biophysical environments and produce relatively stable yields with a minimum of external inputs while supporting their communities’ food security.

Although there is a high probability that the introduction of transgenic crops will enter centers of genetic diversity, it is crucial to protect areas of peasant agriculture free of contamination from GMO crops, as traits important to indigenous farmers (resistance to drought, food or fodder quality, maturity, competitive ability, performance on intercrops, storage quality, taste or cooking properties, compatibility with household labor conditions, etc.) could be traded for transgenic qualities (i.e. herbicide resistance) which are of no importance to farmers that don’t use agrochemicals. Under this scenario risk will increase and farmers will lose their ability to produce relatively stable yields with a minimum of external inputs under changing biophysical environments. The social impacts of local crop shortfalls, resulting from changes in the genetic integrity of local varieties due to genetic pollution, can be considerable in the margins of the developing world.

Maintaining pools of genetic diversity, geographically isolated from any possibility of cross fertilization or genetic pollution from uniform transgenic crops will create “islands” of intact germplasm which will act as extant safeguards against the potential ecological failure derived from the second green revolution increasingly being imposed with programs such as the Gates-Rockefeller AGRA in Africa. These genetic sanctuary islands will serve as the only source of GMO free seeds that will be needed to repopulate the organic farms in the North inevitably contaminated by the advance of transgenic agriculture. The small farmers and indigenous communities of the Global South, with the solidarious help of scientists and NGOs, can continue being the creators and guardians of a biological and genetic diversity that has enriched the food culture of the whole planet.

5. Small farms cool the climate

While industrial agriculture contributes directly to climate change through no less than one third of total emissions of the major greenhouse gases ”” Carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O), small biodiverse organic farms have the opposite effect by increasing the sequestration of carbon in soils.  Small farmers usually treat their soils with organic compost materials which absorb and sequester carbon better than soils that are farmed with conventional fertilizers. Researchers have suggested that the conversion of 10,000 small to medium sized farms to organic production, would allow to store so much carbon in the soil that it would be equivalent to taking 1,174,400 cars off the road.

Further climate amelioration contributions by small farms accrue from the fact that most use significantly less fossil fuel in comparison to conventional agriculture mainly due to a reduction of chemical fertilizer and pesticide use relying instead on organic manures, legume-based rotations and diversity schemes to enhance beneficial insects. Farmers that live in rural communities near cities and towns and linked to local markets, avoid the energy wasted and the gas emissions associated with transporting food hundreds and even thousands of miles.

Conclusions

A salient feature of small farming systems is their high levels of agrobiodiversity arranged in the form of variety mixtures, polycultures, crop-livestock combinations and/or agroforestry patterns. Modelling new agroecosystems using such diversified designs are extremely valuable to farmers whose systems are collapsing due to debt, pesticide or transgenic treadmills or climate change, as diverse systems buffer against natural or human-induced variations in production conditions. There is much to learn from indigenous modes of production, as these systems have a strong ecological basis, maintain valuable genetic diversity and lead to regeneration and preservation of biodiversity and natural resources. Traditional methods are particularly instructive because they provide long-term perspective on successful agricultural management under conditions of climatic variability.

Organized social rural movements in the South oppose industrial agriculture in all its manifestations and increasingly their territories constitute isolated areas rich in unique agrobiodiversity, including genetic diverse material, therefore acting as extant safeguards against the potential ecological failure derived from inappropriate agricultural modernization schemes. It is precisely the ability to generate and maintain diverse crop genetic resources that offer “unique” niche possibilities to small farmers that cannot be replicated by farmers in the North condemned to uniform cultivars and to co-exist with GMOs. The “ cibo pulito, justo e buono” that Slow Food promotes, the Fair Trade coffee, bananas, and the organic products so much in demand by northern consumers can only be produced in the agroecological islands of the South. This “difference” inherent to traditional systems, can be strategically utilized to revitalize small farming communities by exploiting unlimited
opportunities that exist for linking traditional agrobiodiversity with local/national/international markets, as long as these activities are justly compensated by the North and all the segments of the market remain under grassroots control.

Consumers of the North can play a major role by supporting these more solidarious and equitable markets which do not perpetuate the colonial model of “agriculture of the poor for the rich”, but rather a model that catapults small biodiverse farms as the basis for strong rural economies in the South. Such economies will not only provide sustainable production of healthy, agroecologically produced, accessible food for all, but will allow indigenous peoples and small farmers to continue their millennial work of building and conserving the agricultural and natural biodiversity on which we all depend now and more so in the future. 

Thanks to Peter Rosset, Researcher at the Center for the Study of Rural Change in Mexico (CECCAM) and Phil Dahl-Bredine, Maryknoll- CEDICAM, Oaxaca, Mexico for helpful comments on the manuscript.