- LAST REVIEWED: 02 June 2017
- LAST MODIFIED: 26 August 2013
- DOI: 10.1093/obo/9780199830060-0117
- LAST REVIEWED: 02 June 2017
- LAST MODIFIED: 26 August 2013
- DOI: 10.1093/obo/9780199830060-0117
In this article, “agroecology” is defined as a comprehensive perspective of agrifood systems including the relationships between the biophysical and sociocultural components and between agrifood systems and the larger biophysical and sociocultural context in which they are embedded. As such, agroecology includes the internal ecology of agroecosystems, their social and cultural components including nutrition and food sovereignty, crop genotype-by-environment interactions including those of transgenic crop varieties, and the positive (ecosystem services) and negative (ecosystems degradation) effects of agroecosystems on the larger environment, especially climate. This is a broad view of agroecology that does not limit the term to the traditional discipline of ecology applied to agricultural production systems. Although “agroecology” is often used to refer to a comprehensive scientific study of agrifood systems in general, it is also commonly used to refer to a perspective and related practice defined as an alternative to the mainstream industrial agriculture in terms of its underlying values and empirical assumptions—that is, as part of the sustainability revolution. Mainstream agriculture focuses on production efficiency in physical and economic terms—that is, output as quantity of harvested crop per unit of input such as land, labor, or nutrients or, in monetary terms, as revenue per unit of investment—and externalizes many negative effects. Agroecology defines efficiency much more broadly. Outputs include not only edible harvest, but also positive contributions to agroecosystem function such as soil structure, nutritional quality, and economic equity. Inputs include factors not part of production costs, such as sunlight, soil, and microbiota. In addition, agroecology attempts to internalize many factors commonly externalized by mainstream agriculture, including costs such as greenhouse gas emissions, water pollutants, malnutrition, and benefits such as biodiversity and other ecosystem services, as well as social benefits such as nutritional status and farmer and farmworker welfare. Thanks to Daniela Soleri, the editors, and two anonymous reviewers for helpful comments on this article.
General Reference Works
The foundations for a distinct type of agrifood system as an explicit reaction to the growing dominance of industrial systems was established by researchers such as Howard 1976 (cited under Soil and Nutrient Management) in the United Kingdom, Robert Rodale in the United States, Rudolf Steiner in Germany, and Hernández Xolocotzi 1985 in Mexico (cited under Traditional and Scientific Knowledge and Management). “Agroecology” as the term for a distinct field of research and practice seems to have appeared in the 1970s with Cox and Atkins 1979, the first major text in English. Wezel, et al. 2009 reviews the evolution of the term “agroecology,” noting that it was first used in 1928. Altieri 1995 is an introductory overview of agroecology that has been very influential. An introductory text suitable for beginning undergraduates is Gliessman 2007. Vandermeer 2009 is a more advanced text, written by an ecologist, and includes an extensive explanation of the basis of agroecology in ecology. Francis, et al. 2003 expanded the definition of “agroecology” beyond production sciences, in line with the definition used in this article. In contrast, a major English-language text dealing with the ecology of agriculture (and critical of agroecology as defined here) from a mainstream perspective is Connor, et al. 2011. See also Méndez, et al. 2013.
Altieri, M. A., J. G. Farrell, et al. 1995. Agroecology: The science of sustainable agriculture. 2d ed. Boulder, CO: Westview.
This book is a foundational introduction to agroecology, critiquing industrial agriculture and calling for an agroecology based on the principles of natural systems. First published in 1987.
Connor, D. J., R. S. Loomis, and K. G. Cassman. 2011. Crop ecology: Productivity and management in agricultural systems. 2d ed. Cambridge, UK: Cambridge Univ. Press.
This book is a prime example of the mainstream agronomic approach to agroecology, which emphasizes crop ecology in industrial systems, with production as the primary goal; it sees industrial agriculture as superior to less input-intensive systems. First published in 1992.
Cox, G. W., and M. D. Atkins. 1979. Agricultural ecology: An analysis of world food production systems. San Francisco: Freeman.
Out-of-print classic that integrates all aspects of agroecology according to the definition used in this article.
Francis, C., G. Lieblein, S. Gliessman, et al. 2003. Agroecology: The ecology of food systems. Journal of Sustainable Agriculture 22.3: 99–118.
Expands the definition of agroecology to include humanities, social sciences, economics, environmental sciences, and ethics. Includes a history of the concept and its application in education in Mexico, Nordic countries, and the United States. Available online for purchase or by subscription.
Gliessman, S. R. 2007. Agroecology: The ecology of sustainable food systems. 2d ed. Boca Raton, FL: CRC Press.
This beginning-level book emphasizes the ecological foundations of agroecology. A companion workbook is also available.
Méndez, Ernesto, Christopher Bacon, and Rose Cohen, eds. 2013. Special Issue: Agroecology and the Transformation of Agri-Food Systems: Transdisciplinary and Participatory Perspectives. Agroecology and Sustainable Food Systems 37.1.
Emphasizes linking research, practice and social transformation for justice, including an article by Gliessman (pp. 19–31) reviewing development of agroecology in Mexico in the 1970s as a form of resistance to the Green Revolution. Available online for purchase or by subscription.
Vandermeer, J. H. 2009. The ecology of agroecosystems. Sudbury, MA: Jones & Bartlett.
This is an upper-division textbook, with a detailed discussion of ecological/biological principles in agroecosystems, as well as coverage of social and political issues from a social justice perspective. This book continues the high standard set by the out-of-print classic in Cox and Atkins 1979.
Wezel, A., S. Bellon, T. Doré, C. Francis, D. Vallod, and C. David. 2009. Agroecology as a science, a movement and a practice: A review. Agronomy for Sustainable Development 29.4: 503–515.
The authors analyze the history and current use and meaning of the term “agroecology,” first used in the 1920s, in different countries (Germany, the United States, Brazil, and France). They conclude that spatial scale has evolved from plot or field scale to the farm or agroecosystem and from a focus on agronomy to a broader focus including food-system–level social and environmental issues. Available online for purchase or by subscription.
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- Accounting for Ecological Capital
- Allocation of Reproductive Resources in Plants
- Animals, Functional Morphology of
- Animals, Reproductive Allocation in
- Animals, Thermoregulation in
- Antarctic Environments and Ecology
- Applied Ecology
- Aquatic Conservation
- Aquatic Nutrient Cycling
- Archaea, Ecology of
- Assembly Models
- Bacterial Diversity in Freshwater
- Benthic Ecology
- Biodiversity and Ecosystem Functioning
- Biodiversity Patterns in Agricultural Systms
- Biological Chaos and Complex Dynamics
- Biome, Alpine
- Biome, Boreal
- Biome, Desert
- Biome, Grassland
- Biome, Savanna
- Biome, Tundra
- Biomes, African
- Biomes, East Asian
- Biomes, Mountain
- Biomes, North American
- Biomes, South Asian
- Bryophyte Ecology
- Butterfly Ecology
- Carson, Rachel
- Chemical Ecology
- Classification Analysis
- Coastal Dune Habitats
- Communities and Ecosystems, Indirect Effects in
- Communities, Top-Down and Bottom-Up Regulation of
- Community Concept, The
- Community Ecology
- Community Genetics
- Community Phenology
- Competition and Coexistence in Animal Communities
- Competition in Plant Communities
- Complexity Theory
- Conservation Biology
- Conservation Genetics
- Coral Reefs
- Darwin, Charles
- Dead Wood in Forest Ecosystems
- De-Glaciation, Ecology of
- Disease Ecology
- Drought as a Disturbance in Forests
- Early Explorers, The
- Earth’s Climate, The
- Eco-Evolutionary Dynamics
- Ecological Dynamics in Fragmented Landscapes
- Ecological Informatics
- Ecological Relevance of Speciation
- Ecology, Microbial (Community)
- Ecology of Emerging Zoonotic Viruses
- Ecosystem Engineers
- Ecosystem Multifunctionality
- Ecosystem Services
- Ecosystem Services, Conservation of
- Elton, Charles
- Endophytes, Fungal
- Energy Flow
- Environments, Extreme
- Ethics, Ecological
- Facilitation and the Organization of Communities
- Fern and Lycophyte Ecology
- Fire Ecology
- Food Webs
- Foraging Behavior, Implications of
- Foraging, Optimal
- Forests, Temperate Coniferous
- Forests, Temperate Deciduous
- Freshwater Invertebrate Ecology
- Genetic Considerations in Plant Ecological Restoration
- Genomics, Ecological
- Geographic Range
- Gleason, Henry
- Greig-Smith, Peter
- Gymnosperm Ecology
- Habitat Selection
- Harper, John L.
- Heavy Metal Tolerance
- Himalaya, Ecology of the
- Host-Parasitoid Interactions
- Human Ecology
- Human Ecology of the Andes
- Hutchinson, G. Evelyn
- Indigenous Ecologies
- Industrial Ecology
- Insect Ecology, Terrestrial
- Introductory Sources
- Invasive Species
- Island Biogeography Theory
- Island Biology
- Kin Selection
- Landscape Dynamics
- Landscape Ecology
- Laws, Ecological
- Legume-Rhizobium Symbiosis, The
- Leopold, Aldo
- Lichen Ecology
- Life History
- Literature, Ecology and
- MacArthur, Robert H.
- Mangrove Zone Ecology
- Marine Fisheries Management
- Mathematical Ecology
- Mating Systems
- Maximum Sustainable Yield
- Metabolic Scaling Theory
- Metacommunity Dynamics
- Metapopulations and Spatial Population Processes
- Microclimate Ecology
- Mutualisms and Symbioses
- Mycorrhizal Ecology
- Natural History Tradition, The
- Networks, Ecological
- Niche Versus Neutral Models of Community Organization
- Nutrient Foraging in Plants
- Odum, Eugene and Howard
- Old Fields
- Ordination Analysis
- Organic Agriculture, Ecology of
- Parental Care, Evolution of
- Patch Dynamics
- Phenotypic Selection
- Philosophy, Ecological
- Phylogenetics and Comparative Methods
- Physiological Ecology of Nutrient Acquisition in Animals
- Physiological Ecology of Photosynthesis
- Physiological Ecology of Water Balance in Terrestrial Anim...
- Plant Disease Epidemiology
- Plant Ecological Responses to Extreme Climatic Events
- Plant-Insect Interactions
- Polar Regions
- Pollination Ecology
- Population Dynamics, Density-Dependence and Single-Species
- Population Dynamics, Methods in
- Population Ecology, Animal
- Population Ecology, Plant
- Population Fluctuations and Cycles
- Population Genetics
- Population Viability Analysis
- Populations and Communities, Dynamics of Age- and Stage-St...
- Predation and Community Organization
- Predator-Prey Interactions
- Reductionism Versus Holism
- Religion and Ecology
- Remote Sensing
- Restoration Ecology
- Ricketts, Edward Flanders Robb
- Seed Ecology
- Serpentine Soils
- Shelford, Victor
- Simulation Modeling
- Soil Biogeochemistry
- Soil Ecology
- Spatial Pattern Analysis
- Spatial Patterns of Species Biodiversity in Terrestrial En...
- Species Extinctions
- Species Responses to Climate Change
- Species-Area Relationships
- Stability and Ecosystem Resilience, A Below-Ground Perspec...
- Stoichiometry, Ecological
- Stream Ecology
- Systems Ecology
- Tansley, Sir Arthur
- Terrestrial Nitrogen Cycle
- Terrestrial Resource Limitation
- Thermal Ecology of Animals
- Tragedy of the Commons
- Trophic Levels
- Vegetation Classification
- Vegetation Mapping
- Weed Ecology
- Whittaker, Robert H.
- Wildlife Ecology