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Ecosystem services and land sparing potential of urban and peri-urban agriculture: A review

Published online by Cambridge University Press:  17 April 2017

Jennifer A. Wilhelm  and
Richard G. Smith
Jennifer A. Wilhelm*
Affiliation:
Department of Natural Resources and the Environment, University of New Hampshire, Durham, New Hampshire 03824, USA Sustainability Institute, University of New Hampshire, Durham, New Hampshire 03824, USA
Richard G. Smith
Affiliation:
Department of Natural Resources and the Environment, University of New Hampshire, Durham, New Hampshire 03824, USA
*
*Corresponding author: [email protected]
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Abstract

Agricultural expansion contributes to the degradation of biodiverse ecosystems and the services these systems provide. Expansion of urban and peri-urban agriculture (UPA), on the other hand, may hold promise to both expand the portfolio of ecosystem services (ES) available in built environments, where ES are typically low and to reduce pressure to convert sensitive non-urban, non-agricultural ecosystems to agriculture. However, few data are available to support these hypotheses. Here we review and summarize the research conducted on UPA from 320 peer-reviewed papers published between 2000 and 2014. Specifically, we explored the availability of data regarding UPA's impact on ES and disservices. We also assessed the literature for evidence that UPA can contribute to land sparing. We find that the growth in UPA research over this time period points to the emerging recognition of the potential role that UPA systems play in food production worldwide. However, few studies (n = 15) place UPA in the context of ES, and no studies in our review explicitly quantify the land sparing potential of UPA. Additionally, while few studies (n = 19) quantify production potential of UPA, data that are necessary to accurately quantify the role these systems can play in land sparing, our rough estimates suggest that agricultural extensification into the world's urban environments via UPA could spare an area approximately twice the size of the US state of Massachusetts. Expanding future UPA research to include quantification of ES and functions would shed light on the ecological tradeoffs associated with agricultural production in the built environment. As food demand increases and urban populations continue to grow, it will be critical to better understand the role urban environments can play in global agricultural production and ecosystem preservation.

Keywords

agroecologyfood securityland usemultifunctional agriculture
Type
Review Article
Information
Renewable Agriculture and Food Systems , Volume 33 , Issue 5 , October 2018 , pp. 481 - 494
Copyright
Copyright © Cambridge University Press 2017 

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References

Abdalla, S.B., Predotova, M., Gebauer, J., and Buerkert, A. 2012. Horizontal nutrient flows and balances in irrigated urban gardens of Khartoum, Sudan. Nutrient Cycling in Agroecosystems 92:119132.Google Scholar
Abdu, N., Abdulkadir, A., Agbenin, J.O., and Buerkert, A. 2011. Vertical distribution of heavy metals in wastewater-irrigated vegetable garden soils of three West African cities. Nutrient Cycling in Agroecosystems 89:387397.Google Scholar
Ackerman, K., Conard, M., Culligan, P., Plunz, R., Sutto, M., and Whittinghill, L. 2014. Sustainable food systems for future cities: The potential of urban agriculture. Economic and Social Review 45:189206.Google Scholar
Agrawal, M., Singh, B., Rajput, M., Marshall, F., and Bell, J.N. 2003. Effect of air pollution on peri-urban agriculture: A case study. Environmental Pollution 126:323329.Google Scholar
Algert, S.J., Baameur, A., and Renvall, M.J. 2014. Vegetable output and cost savings of community gardens in San Jose, California. Journal of the Academy of Nutrition and Dietetics 114:10721076.Google Scholar
Altieri, M.A. 2004. Linking ecologists and traditional farmers in the search for sustainable agriculture. Frontiers in Ecology and the Environment 2:3542.Google Scholar
Amoah, P., Drechsel, P., Abaidoo, R.C., and Henseler, M. 2007. Irrigated urban vegetable production in Ghana: Microbiological contamination in farms and markets and associated consumer risk groups. Journal of Water and Health 5:455466.Google Scholar
Bagstad, K.J. and Shammin, M.R. 2012. Can the genuine progress indicator better inform sustainable regional progress?-A case study for Northeast Ohio. Ecological Indicators 18:330341.Google Scholar
Barthel, S. and Isendahl, C. 2013. Urban gardens, agricultures and waters management: Sources of resilience for long-term food security in cities. Ecological Economics 86:215225.Google Scholar
Bazeley, P. and Jackson, K. 2013. Qualitative Data Analysis with NVivo. 2nd ed. London, UK, Sage Publications Ltd.Google Scholar
Bolund, P. and Hunhammar, S. 1999. Ecosystem services in urban areas. Ecological Economics 29:293301.Google Scholar
Bommarco, R., Kleijn, D., and Potts, S.G. 2013. Ecological intensification: Harnessing ecosystem services for food security. Trends in Ecology and Evolution 28:230238.Google Scholar
Brinkley, C. 2012. Evaluating the benefits of peri-urban agriculture. Journal of Planning Literature 27:259269.Google Scholar
Bryld, E. 2003. Potentials, problems, and policy implications for urban agriculture in developing countries. Agriculture and Human Values 20:7986.Google Scholar
Calvet-Mir, L., Gomez-Baggethun, E., and Reyes-Garcia, V. 2012. Beyond food production: Ecosystem services provided by home gardens. A case study in Vall Fosca, Catalan Pyrenees, Northeastern Spain. Ecological Economics 74:153160.Google Scholar
Carpenter, S.R., Mooney, H.A., Agard, J., Capistrano, D., DeFries, R.S., Diaz, S., Dietz, T., Duraiappah, A.K., Oteng-Yeboah, A., Pereira, H.M., Perrings, C., Reid, W.V., Sarukhan, J., Scholes, R.J., and Whyte, A. 2009. Science for managing ecosystem services: Beyond the millennium ecosystem assessment. Proceedings of the National Academy of Sciences of the United States of America 106:13051312.Google Scholar
Cheema, G.S., Smit, J., Ratta, A., and Nasr, J. 1996. Urban Agriculture: Food, Jobs, and Sustainable Cities. United Nation Development Programme, New York, NY.Google Scholar
Clark, K.H. and Nicholas, K.A. 2013. Introducing urban food forestry: A multifunctional approach to increase food security and provide ecosystem services. Landscape Ecology 28:16491669.Google Scholar
Cohen, N. and Reynolds, K. 2014. Urban agriculture policy making in New York's “New Political Spaces” strategizing for a participatory and representative system. Journal of Planning Education and Research 34:221234.Google Scholar
Colasanti, K.J.A., Hamm, M.W., and Litjens, C.M. 2012. The city as an “agricultural powerhouse?” Perspectives on expanding urban agriculture from Detroit, Michigan. Urban Geography 33:348369.Google Scholar
Diaz Rizo, O., Hernandez Merlo, M., Echeverria Castillo, F., and Arado Lopez, J.O. 2012. Assessment of metal pollution in soils from a former Havana (Cuba) solid waste open dump. Bulletin of Environmental Contamination and Toxicology 88:182186.Google Scholar
Donald, P., Green, R., and Heath, M. 2001. Agricultural intensification and the collapse of Europe's farmland bird populations. Proceedings of the Royal Society B-Biological Sciences 268:2529.Google Scholar
Edmondson, J.L., Davies, Z.G., Gaston, K.J., and Leake, J.R. 2014. Urban cultivation in allotments maintains soil qualities adversely affected by conventional agriculture. Journal of Applied Ecology 51:880889.Google Scholar
Egan, J.F. and Mortensen, D.A. 2012. A comparison of land-sharing and land-sparing strategies for plant richness conservation in agricultural landscapes. Ecological Applications 22:459471.Google Scholar
Egwu, G.N. and Agbenin, J.O. 2013. Field assessment of cadmium, lead and zinc contamination of soils and leaf vegetables under urban and peri-urban agriculture in northern Nigeria. Archives of Agronomy and Soil Science 59:875887.Google Scholar
Farrugia, S., Hudson, M.D., and McCulloch, L. 2013. An evaluation of flood control and urban cooling ecosystem services delivered by urban green infrastructure. International Journal of Biodiversity Science, Ecosystem Services & Management 9:136145.Google Scholar
Fischer, J., Brosi, B., Daily, G.C., Ehrlich, P.R., Goldman, R., Goldstein, J., Lindenmayer, D.B., Manning, A.D., Mooney, H.A., Pejchar, L., Ranganathan, J., and Tallis, H. 2008. Should agricultural policies encourage land sparing or wildlife-friendly farming? Frontiers in Ecology and the Environment 6:380385.Google Scholar
Fischer, J., Abson, D.J., Butsic, V., Chappell, M.J., Ekroos, J., Hanspach, J., Kuemmerle, T., Smith, H.G., and von Wehrden, H. 2014. Land sparing versus land sharing: Moving forward. Conservation Letters 7:149157.Google Scholar
Flynn, K.C. 2001. Urban agriculture in Mwanza, Tanzania. Africa 71:666691.Google Scholar
Foley, J.A., Ramankutty, N., Brauman, K.A., Cassidy, E.S., Gerber, J.S., Johnston, M., Mueller, N.D., O'Connell, C., Ray, D.K., West, P.C., Balzer, C., Bennett, E.M., Carpenter, S.R., Hill, J., Monfreda, C., Polasky, S., Rockstrom, J., Sheehan, J., Siebert, S., Tilman, D., and Zaks, D.P.M. 2011. Solutions for a cultivated planet. Nature 478:337342.Google Scholar
Gomez-Baggethun, E. and Barton, D.N. 2013. Classifying and valuing ecosystem services for urban planning. Ecological Economics 86:235245.Google Scholar
Grau, R., Kuemmerle, T., and Macchi, L. 2013. Beyond ‘land sparing versus land sharing’: Environmental heterogeneity, globalization and the balance between agricultural production and nature conservation. Current Opinion in Environmental Sustainability 5:477483.Google Scholar
Green, R.E., Cornell, S.J., Scharlemann, J.P.W., and Balmford, A. 2005. Farming and the fate of wild nature. Science 307:550555.Google Scholar
Grewal, S.S. and Grewal, P.S. 2012. Can cities become self-reliant in food? Cities 29:111.Google Scholar
Hale, I.L., Wollheim, W.M., Smith, R.G., Asbjornsen, H., Brito, A.F., Broders, K., Grandy, A.S., and Rowe, R. 2014. A scale-explicit framework for conceptualizing the environmental impacts of agricultural land use change. Sustainability 6:84328451.Google Scholar
Hamilton, A.J., Burry, K., Mok, H., Barker, S.F., Grove, J.R., and Williamson, V.G. 2014. Give peas a chance? Urban agriculture in developing countries. A review. Agronomy for Sustainable Development 34:4573.Google Scholar
Hara, Y., Tsuchiya, K., Matsuda, H., Yamamoto, Y., and Sampei, Y. 2013. Quantitative assessment of the Japanese “local production for local consumption” movement: A case study of growth of vegetables in the Osaka city region. Sustainability Science 8:515527.Google Scholar
Jacobson, M.Z. 2010. Enhancement of local air pollution by urban CO2 domes. Environmental Science and Technology 44:24972502.Google Scholar
Jenerette, G.D., Harlan, S.L., Stefanov, W.L., and Martin, C.A. 2011. Ecosystem services and urban heat riskscape moderation: Water, green spaces, and social inequality in Phoenix, USA. Ecological Applications 21:26372651.Google Scholar
Jenkins, M., Green, R., and Madden, J. 2003. The challenge of measuring global change in wild nature: Are things getting better or worse? Conservation Biology 17:2023.Google Scholar
Kaethler, T.M. 2006. Growing Space: The Potential of Urban Agriculture in the City of Vancouver. University of British Columbia School of Community and Regional Planning, Vancouver. Viewed 30 November 2015. Available at Web site http://community-wealth.org/sites/clone.community-wealth.org/files/downloads/report-kaethler.pdfGoogle Scholar
Keraita, B., Drechsel, P., and Konradsen, F. 2008. Perceptions of farmers on health risks and risk reduction measures in wastewater-irrigated urban vegetable farming in Ghana. Journal of Risk Research 11:10471061.Google Scholar
Klinkenberg, E., McCall, P.J., Wilson, M.D., Amerasinghe, F.P., and Donnelly, M.J. 2008. Impact of urban agriculture on malaria vectors in Accra, Ghana. Malaria Journal 7:151.Google Scholar
Knight, A., Cheng, Z., Grewal, S.S., Islam, K.R., Kleinhenz, M.D., and Grewal, P.S. 2013. Soil health as a predictor of lettuce productivity and quality: A case study of urban vacant lots. Urban Ecosystems 16:637656.Google Scholar
Kulak, M., Graves, A., and Chatterton, J. 2013. Reducing greenhouse gas emissions with urban agriculture: A Life Cycle Assessment perspective. Landscape and Urban Planning 111:6878.Google Scholar
Kuo, F. and Sullivan, W. 2001. Environment and crime in the inner city - Does vegetation reduce crime? Environment and Behavior 33:343367.Google Scholar
Kurian, M., Reddy, V.R., Dietz, T., and Brdjanovic, D. 2013. Wastewater re-use for peri-urban agriculture: A viable option for adaptive water management? Sustainability Science 8:4759.Google Scholar
La Rosa, D., Barbarossa, L., Privitera, R., and Martinico, F. 2014. Agriculture and the city: a method for sustainable planning of new forms of agriculture in urban contexts. Land Use Policy 41:290303.Google Scholar
Larondelle, N. and Haase, D. 2013. Urban ecosystem services assessment along a rural-urban gradient: A cross-analysis of European cities. Ecological Indicators 29:179190.Google Scholar
Lichtfouse, E., Hamelin, M., Navarrete, M., Debaeke, P., and Henri, A. 2010. Emerging agroscience. Agronomy for Sustainable Development 30:110.Google Scholar
Li, F., Wang, R.S., Paulussen, J., and Liu, X.S. 2005. Comprehensive concept planning of urban greening based on ecological principles: A case study in Beijing, China. Landscape and Urban Planning 72:325336.Google Scholar
Livesley, S.J., Dougherty, B.J., Smith, A.J., Navaud, D., Wylie, L.J., and Arndt, S.K. 2010. Soil-atmosphere exchange of carbon dioxide, methane and nitrous oxide in urban garden systems: Impact of irrigation, fertiliser and mulch. Urban Ecosystems 13:273293.Google Scholar
Lovell, S.T. 2010. Multifunctional urban agriculture for sustainable land use planning. Sustainability 2:24992522.Google Scholar
Lovell, S.T. and Johnston, D.M. 2009. Designing landscapes for performance based on emerging principles in landscape ecology. Ecology and Society 14:44.Google Scholar
Lowder, S.K., Skoet, J., and Singh, S. 2014. What do we really know about the number and distribution of farms and family farms worldwide? Background paper for The State of Food and Agriculture 2014. ESA Working Paper No. 14-02. Rome, FAO. Available at Web site http://www.fao.org/docrep/019/i3729e/i3729e.pdfGoogle Scholar
Lowenstein, D.M., Matteson, K.C., Xiao, I., Silva, A.M., and Minor, E.S. 2014. Humans, bees, and pollination services in the city: The case of Chicago, IL (USA). Biodiversity and Conservation 23:28572874.Google Scholar
Lydecker, M. and Drechsel, P. 2010. Urban agriculture and sanitation services in Accra, Ghana: The overlooked contribution. International Journal of Agricultural Sustainability 8:94103.Google Scholar
Lyytimaki, J. and Sipila, M. 2009. Hopping on one leg - The challenge of ecosystem disservices for urban green management. Urban Forestry & Urban Greening 8:309315.Google Scholar
MacRae, R., Gallant, E., Patel, S., Michalak, M., Bunch, M., and Schaffner, S. 2010. Could Toronto provide 10% of its fresh vegetable requirements from within its own boundaries? Matching consumption requirements with growing spaces. Journal of Agriculture, Food Systems, and Community Development 1:105127.Google Scholar
Marques-Perez, I., Segura, B., and Maroto, C. 2014. Evaluating the functionality of agricultural systems: Social preferences for multifunctional peri-urban agriculture. The “Huerta de Valencia” as case study. Spanish Journal of Agricultural Research 12:889901.Google Scholar
Martellozzo, F., Landry, J.S., Plouffe, D., Seufert, V., Rowhani, P., and Ramankutty, N. 2014. Urban agriculture: A global analysis of the space constraint to meet urban vegetable demand. Environmental Research Letters 9:064025.Google Scholar
Matagi, S.V. 2002. Some issues of environmental concern in Kampala, the capital city of Uganda. Environmental Monitoring and Assessment 77:121138.Google Scholar
McClintock, N., Cooper, J., and Khandeshi, S. 2013. Assessing the potential contribution of vacant land to urban vegetable production and consumption in Oakland, California. Landscape and Urban Planning 111:4658.Google Scholar
McLain, R., Poe, M., Hurley, P.T., Lecompte-Mastenbrook, J., and Emery, M.R. 2012. Producing edible landscapes in Seattle's urban forest. Urban Forestry & Urban Greening 11:187194.Google Scholar
Merson, J., Attwater, R., Ampt, P., Wildman, H., and Chapple, R. 2010. The challenges to urban agriculture in the Sydney basin and lower Blue Mountains region of Australia. International Journal of Agricultural Sustainability 8:7285.Google Scholar
Millennium Ecosystem Assessment (MA). 2005. Ecosystems and Human Well-Being: Synthesis, Volume 155. Island Press, Washington, p. 40.Google Scholar
Moore, S.R. 2010. Energy efficiency in small-scale biointensive organic onion production in Pennsylvania, USA. Renewable Agriculture and Food Systems 25:181188.Google Scholar
Niblick, B., Monnell, J.D., Zhao, X., and Landis, A.E. 2013. Using geographic information systems to assess potential biofuel crop production on urban marginal lands. Applied Energy 103:234242.Google Scholar
Orsini, F., Gasperi, D., Marchetti, L., Piovene, C., Draghetti, S., Ramazzotti, S., Bazzocchi, G., and Gianquinto, G. 2014. Exploring the production capacity of rooftop gardens (RTGs) in urban agriculture: The potential impact on food and nutrition security, biodiversity and other ecosystem services in the city of Bologna. Food Security 6:781792.Google Scholar
Owusu, F. 2007. Conceptualizing livelihood strategies in African cities - Planning and development implications of multiple livelihood strategies. Journal of Planning Education and Research 26:450465.Google Scholar
Power, A.G. 2010. Ecosystem services and agriculture: Tradeoffs and synergies. Philosophical Transactions of the Royal Society B-Biological Sciences 365:29592971.Google Scholar
Qiu, G.Y., Li, H.Y., Zhang, Q.T., Chen, W., Liang, X.J., and Li, X.Z. 2013. Effects of evapotranspiration on mitigation of urban temperature by vegetation and urban agriculture. Journal of Integrative Agriculture 12:13071315.Google Scholar
QSR International Pty Ltd. 2010. NVivo qualitative data analysis Software. Version 9.Google Scholar
Ramankutty, N., Evan, A.T., Monfreda, C., and Foley, J.A. 2008. Farming the planet: 1. Geographic distribution of global agricultural lands in the year 2000. Global Biogeochemical Cycles 22:GB1003.Google Scholar
Redwood, M. 2009. Tenure and land markets for urban agriculture. Open House International 34:814.Google Scholar
Renting, H., Rossing, W.A.H., Groot, J.C.J., Van der Ploeg, J.D., Laurent, C., Perraud, D., Stobbelaar, D.J., and Van Ittersum, M.K. 2009. Exploring multifunctional agriculture. A review of conceptual approaches and prospects for an integrative transitional framework. Journal of Environmental Management 90:S112S123.Google Scholar
Smit, J., Nasr, J., and Ratta, A. 2001. Chapter 2: Urban Agriculture Yesterday and Today. In: Urban Agriculture: Food Jobs and Sustainable Cities (2001 edition, published with permission from the United Nations Development Programme). The Urban Agriculture Network, Inc. Available at Web site http://www.jacsmit.com/book/Chap02.pdfGoogle Scholar
Taylor, J.R. and Lovell, S.T. 2014. Urban home food gardens in the Global North: Research traditions and future directions. Agriculture and Human Values 31:285305.Google Scholar
Tilman, D., Cassman, K.G., Matson, P.A., Naylor, R., and Polasky, S. 2002. Agricultural sustainability and intensive production practices. Nature 418:671677.Google Scholar
Tilman, D., Balzer, C., Hill, J., and Befort, B.L. 2011. Global food demand and the sustainable intensification of agriculture. Proceedings of the National Academy of Sciences of the United States of America 108:2026020264.Google Scholar
United Nations (UN), Population Division. 2012. World Population Prospects. Volume II. Viewed May 8, 2015. Available at Web site http://esa.un.org/unpd/wpp/index.htmGoogle Scholar
United Nations (UN), Population Division. 2014. World Urbanization Prospects. Highlights. Viewed May 8, 2015. Available at Web site http://esa.un.org/unpd/wpp/index.htmGoogle Scholar
van Heezik, Y.M., Dickinson, K.J.M., and Freeman, C. 2012. Closing the gap: Communicating to change gardening practices in support of native biodiversity in urban private gardens. Ecology and Society 17:34.Google Scholar
Wortman, S.E. and Lovell, S.T. 2013. Environmental challenges threatening the growth of urban agriculture in the United States. Journal of Environmental Quality 42:12831294.Google Scholar
Yadav, P., Duckworth, K., and Grewal, P.S. 2012. Habitat structure influences below ground biocontrol services: A comparison between urban gardens and vacant lots. Landscape and Urban Planning 104:238244.Google Scholar
Yeudall, F., Sebastian, R., Cole, D.C., Ibrahim, S., Lubowa, A., and Kikafunda, J. 2007. Food and nutritional security of children of urban farmers in Kampala, Uganda. Food and Nutrition Bulletin 28:S237S246.Google Scholar
Zasada, I. 2011. Multifunctional peri-urban agriculture-A review of societal demands and the provision of goods and services by farming. Land Use Policy 28:639648.Google Scholar
Zezza, A. and Tasciotti, L. 2010. Urban agriculture, poverty, and food security: Empirical evidence from a sample of developing countries. Food Policy 35:265273.Google Scholar
Zhang, F., Cai, J., and Liu, G. 2009. How urban agriculture is reshaping peri-urban Beijing? Open House International 34:1524.Google Scholar
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