Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-05T02:53:30.442Z Has data issue: false hasContentIssue false
  • English
  • Français

Analysis of the transport of imported food in Spain and its contribution to global warming

Published online by Cambridge University Press:  12 December 2014

David Pérez Neira ,
Xavier Simón Fernández ,
Damián Copena Rodríguez ,
Marta Soler Montiel  and
Manuel Delgado Cabeza
David Pérez Neira*
Affiliation:
Universidad Pablo de Olavide, Sevilla, Spain Prometeo Researcher, Secretaria de Educación Superior, Ciencia Tecnología eInnovación de la República del Ecuador, Universidad Estatal de Milagro, Milagro, Ecuador
Xavier Simón Fernández
Affiliation:
Universidade de Vigo, Vigo, Spain
Damián Copena Rodríguez
Affiliation:
Universidade de Vigo, Vigo, Spain
Marta Soler Montiel
Affiliation:
Universidad de Sevilla, Sevilla, Spain
Manuel Delgado Cabeza
Affiliation:
Universidad de Sevilla, Sevilla, Spain
*
*Corresponding author: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Through the process of globalization, food has experienced an intense territorial restructuring process. Local agric-food links have weakened at the same time as daily products arrived from distant lands. There is presently a wide international debate on the importance of transport in the configuration of the agric-food system and its contribution in terms of greenhouse gas (GHG). The direct environmental costs of the transport of imported food, that is the ‘external food miles’, have been estimated in kilometer (km), ton (t), ton-kilometer (t-km) and GHG in Spain between 1995 and 2011. The analysis is made by ten food groups including 136 products, with special attention to the most important ones (cereals and animal feed), as well as by means of transport (air, rail, road and water) and from 113 different countries belonging to six geographical areas. Two phases are identified during this period: an expansive phase (1995–2007), in which the t-km of imported food increased from 81.8 to 147.8 million t-km and environmental pressure rose from 3.1 to 5.4 million CO2-eq t, and a recession phase (2007–2011), in which environmental pressure subsided as a consequence of the reduction of imports, even though it still remained above the 1995 level. The article reveals a clear interrelation between amounts, distances and modal distribution when it comes to determining the environmental cost of transporting food imports in the two periods studied. It also reflects on the role of the external food miles in the Spanish agri-food system from a sustainability perspective.

Keywords

agri-food systemimportstransportfood milessustainability
Type
Research Papers
Information
Renewable Agriculture and Food Systems , Volume 31 , Issue 1 , February 2016 , pp. 37 - 48
Check for updates
Copyright
Copyright © Cambridge University Press 2014 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1McMichael, P. 2005. Global development and the corporate food regime. In Buttel, F.H. and McMichael, P. (eds). New Directions in the Sociology of Global Development. Elsevier Press, Oxford. p. 265–299.Google Scholar
2Ploeg, J.D. van der 2008. New Peasantries. Struggles for Autonomy and Sustainability in an Era of Empire and Globalization. Earthscan, London and Sterling, VA.Google Scholar
3Goland, C. and Bauer, S. 2004. When the apple falls close to the tree: Local food systems and the preservation of diversity. Renewable Agriculture and Food Systems 19(4):228236.CrossRefGoogle Scholar
4McMichael, P. 2009. A food regime genealogy. Journal of Peasant Studies 36(1):139169.CrossRefGoogle Scholar
5Nashawi, I., Malallah, A., and Al-Bisharah, M. 2010. Forecasting world crude oil production using multicyclic Hubbert model. Energy Fuels 24:17881800.Google Scholar
6Zhang, M., Li, H., Zhou, M., and Mu, H. 2011. Decomposition analysis of energy consumption in Chinese transportation sector. Applied Energy 88:22792285.Google Scholar
7EU (European Union). 2013. EU Energy in Figures. Statistical Pocketbook 2013. Available at Web site http://ec.europa.eu/energy/publications/doc/2013_pocketbook.pdf) (accessed September 16, 2013).Google Scholar
8IDAE. 2013. Balances Energéticos Anuales. In: Instituto para la Diversificación y Ahorro de Energía. Available at Web site http://www.idae.es/ (accessed September 10, 2013).Google Scholar
9Huang, H., von Lampe, M., and van Tongeren, F. 2011. Climate change and trade in agriculture. Food Policy 36:S9S13.Google Scholar
10Sim, S., Barry, M., Clift, R., and Cowell, S.J. 2007. The relative importance of transport in determining an appropriate sustainability strategy for food sourcing. International Journal of Live Cycle Assessment 12(6):422431.Google Scholar
11Munksgaard, J. and Pedersen, K.A. 2001. CO2 accounts for open economies: Producer or consumer responsibility? Energy Policy 29:327334.Google Scholar
12Kondo, Y., Moriguchi, Y., and Shimizu, H. 1998. CO2 emissions in Japan: Influences of imports and exports. Applied Energy 59(2–3):163174.Google Scholar
13Ferng, J.-J. 2003. Allocating the responsibility of CO2 over-emissions from the perspectives of benefit principle and ecological deficit. Ecological Economics 46:121141.Google Scholar
14Subak, S. 1995. Methane embodied in the international trade of commodities: Implications for global emissions. Global Environmental Change 5(5):433446.Google Scholar
15Dauvergne, P. 2008. The Shadows of Consumption—Consequences for the Global Environment. MIT Press, Cambridge, MA.Google Scholar
16Kissinger, M. and Rees, W.E. 2009. Footprints on the prairies: Degradation and sustainability of Canadian agricultural land in a globalizing world. Ecological Economics 68:23092315.Google Scholar
17Peters, G.P. 2008. From production-based to consumption-based national emission inventories. Ecological Economics 65:1323.Google Scholar
18Schipper, L., Scholl, L., and Price, L. 1997. Energy use and carbon emissions from freight in 10 industrialized countries: an analysis of trends from 1973 to 1992. Transportation Research Part D: Transport and Environment. 2:5776.Google Scholar
19Janic, M. 2007. Modeling the full cost of and intermodal and road freight transport network. Transportation Research Part D: Transport and Environment. 12:3344.Google Scholar
20Paxton, A. 1994. The Food Miles Report: The Dangers of Long Distance Food Transport. In Safe Alliance, London.Google Scholar
21Weber, L. and Scott, H. 2008. Food-miles and the relative climate impacts of food choices in the United States. Environmental Science and Technology 42:35033513.Google Scholar
22Engelhaupt, E. 2008. Do food miles matter? Environmental Science and Technology 42(10):34823482.CrossRefGoogle ScholarPubMed
23Coley, D., Howard, M., and Winter, B.M. 2009. Local food, food miles and carbon emissions: A comparison of farm shop and mass distribution approaches. Food Policy 34:150154.CrossRefGoogle Scholar
24Lal, R., Griyn, M., Apt, J., Lave, L., and Morgan, M.G. 2004. Managing soil carbon. Science 16:304393.Google Scholar
25Durham, C.A., King, R.P., Delgado, C.A., and Roheim, M. 2009. Consumer definitions of ‘locally grown’ for fresh fruits and vegetables. Journal of Food Distribution Research 40:5662.Google Scholar
26Peters, C.J., Bills, N.L., Lembo, A.J., Wilkins, J.L., and Fick, G.W. 2008. Mapping potential foodsheds in New York State: A spatial model for evaluating the capacity to localize food production. Renewable Agriculture and Food Systems 24(1):7284.Google Scholar
27Gliessman, S. 2007. Agroecology: The Ecology of Sustainable Food System. CRC Press, Boca Raton.Google Scholar
28Francis, C.A. 2009. Conventional research on controversial issues: An exercise in futility? Renewable Agriculture and Food Systems 25(1):37.Google Scholar
29Ploeg, J.D. van der, Renting, H., Brunori, G., Knickel, K., Mannion, J., Marsden, T.K., Roest, K., Sevilla Guzmán, E., and Ventura, F. 2000. Rural development: From practices and policies towards theory. Sociologia Ruralis 40(4):391408.Google Scholar
30Kissinger, M. 2012. International trade related food miles—the case of Canada. Food Policy 37:171178.Google Scholar
31Peter, G.P. and Hertwich, E.G. 2008. CO2 embodied in international trade with implications for global climate policy. Environmental, Science and Technology 42(5):14011407.Google Scholar
32Heller, M.C. and Koelain, G.A. 2003. Assessing the sustainability of the US food system: A life cycle perspective. Agricultural Systems 76:10071041.Google Scholar
33Williams, A.G., Pell, R., Webb, J., Tribe, E., Evans, D., Moorhouse, E., and Watkiss, P. 2008. Comparative Life Cycle Assessment of Food Commodities Procured for UK Consumption Through a Diversity of Supply Chains. Final Report for Defra Project FO0103. Available at Web site http://randd.defra.gov.uk/Default.aspx?Module=More&Location=None&ProjectID=15001 (accessed May 10, 2014).Google Scholar
34Knudsen, M.T., Yu-Hui, Q., Yan, L., and Halberg, N. 2010. Environmental assessment of organic soybean (Glycine max) imported from China to Denmark: A case study. Journal of Cleaner Production 18:14311439.Google Scholar
35Knudsen, M.T., Fonseca de Almeida, G., Langer, V., Santiago de Abreru, L., and Halberg, N. 2011. Environmental assessment of organic juice imported to Denmark: A case study on oranges (Citrus sinensis) from Brazil. Organic Agriculture 1:167185.Google Scholar
36MITC. 2014. Estadísticas de Comercio Español. In: Ministerio de Industria, Turismo y Comercio. Available at Web site http://datacomex.comercio.es (accessed May 10, 2014).Google Scholar
37MAGRAMA. 2014. Anuario de Estadística Agraria. Ministerio de Agricultura, Alimentación y Medio Ambiente. Available at Web site http://www.magrama.gob.es/gl/estadistica/temas/default.aspx (accessed May 15, 2014).Google Scholar
38Pirog, R. and Benjamin, A. 2005. Calculating Food Miles for a Multiple Ingredient Food Product. Leopold Center for Sustainable Agriculture, Iowa State University. Available at Web site http://www.leopold.iastate.edu/sites/default/files/pubs-and-papers/2005-03-calculating-food-miles-multiple-ingredient-food-product.pdf (accessed May 10, 2014).Google Scholar
39Corre, W., Schroder, J., and Verhagen, J. 2003. Energy Use in Conventional and Organic Farming Systems. Proceedings No. 511. International Fertiliser Society, New York.Google Scholar
40IPCC. 2006. Guidelines for National Greenhouse Inventories. Vol. 2, Number 2. Available at Web site http://www.ipcc-nggip.iges.or.jp/public/2006gl/pdf/2_Volume2/V2_3_Ch3_Mobile_Combustion.pdf (accessed November 10, 2011).Google Scholar
41Blanke, M.M. and Burdick, B. 2005. Food (miles) for thought. Environmental Science and Pollution Research 12:125127.CrossRefGoogle ScholarPubMed
42Advenier, P., Boisson, P., Delaure, C., Douaud, A., Girad, C., and Legendre, M. 2002. Energy efficiency and CO2 emissions of road transportation: Comparative analysis of technologies and fuels. Energy and Environment 13:631646.Google Scholar
43Ang-Olson, J. and Schroeer, W. 2002. Energy efficiency strategies for freight trucking. Transportation Research Record: Journal of the Transportation Research Board 1815:1118.Google Scholar
44Kristensen, H.O. 2002. Transport by sea and road—technical and economical environmental factors. Transportation Research Part D: Transport and Environment. 4:265290.Google Scholar
45ICF. 2009. Comparative Evaluation of Rain and Truck Fuel Efficiency on Competitive Corridors. In IFC International, Department of Transportation, Office of Policy and Communications.Google Scholar
46Lenzen, M. 1999. Total requirements of energy and greenhouse gases for Australian transport. Transportation Research Part D 4:107174.Google Scholar
47Kamakaté, F. and Schipper, L. 2008. Trends in truck freight energy use and carbon emissions in selected OECD countries from 1973 to 2005. Energy Policy 37:37433751.Google Scholar
48Pérez Martínez, P.J. 2009. The vehicle approach for freight road transport energy and environmental analysis in Spain. Transportation Research Review 1(2):7585.Google Scholar
49Saari, A., Lettenmeier, M., Pusenius, K., and Hakkarainen, E. 2007. Influence of vehicle type and road category on natural resource consumption in road transport. Transportation Research Part 2(1):2332.Google Scholar
50Steenhof, P., Woudsama, C., and Sparling, E. 2006. Greenhouse gas emissions and the surface transport of freight in Canada. Transportation Research D: Transport and Environment 11:369376.Google Scholar
51UIC. 2008. Rail transport and Environment. Facts and Figures. UIC. Available at Web site http://www.etc-corporate.org/resources/uploads/railways&environment_facts&figures.pdf (accessed March 4, 2011).Google Scholar
52WEC. 2004. Comparison Energy Systems Using Life Cycle Assessment. Word Energy Council. Available on Web site http://www.worldenergy.org/documents/lca2.pdf (accessed November 10, 2012).Google Scholar
53IMO. 2008. Greenhouse Gas Emissions from Ships. Phase 1 Report. International Maritime Organization. Available at Web site http://www.imo.org/blast/blastDataHelper.asp?data_id=26402&filename=INF-6.pdf (accessed May 10, 2014).Google Scholar
54Tassou, S.A., De-Lille, G., and Ge, Y.T. 2009. Food transport refrigeration—approaches to reduce energy consumption and environmental impacts of road transport. Applied Thermal Engineering 29:14671477.Google Scholar
55Van Wee, B., Janse, P., and van Den Brink, R. 2005. Comparing energy use and environmental performance of land transport modes. Transport Reviews 34:324.Google Scholar
56Copena, D., Simón Fernández, X., Pérez Neira, D., Delgado Cabeza, M., and Soler Montiel, M. 2011. Coste energético, huella ecológica del carbono y emisiones de CO2 de las importaciones de alimentos en el estado español. Informe Amigos de la Tierra.Google Scholar
57INE. 2014. Instituto Nacional de Estadística. Available at Web site http://www.ine.es/ (accessed May 20, 2014)Google Scholar
58Schlich, E. and Fleissner, U. 2005. The ecology of scale: Assessment of regional energy turnover and comparison with global food. International Journal of Life Cycle Assessment 10(3):219223.Google Scholar
59Edwards-Jones, G., Milà i Canals, L., Hounsome, N., Truninger, M., Koerber, G., Hounsome, B., Cross, P., York, E.H., Hospido, A., Plassmann, K., Harris, I.M., Edwards, R.T., Dayd, G.A.S., Tomos, D., Cowell, S.J., and Jones, D.L. 2008. Testing the assertion that ‘local food is best’: The challenges of an evidence-based approach. Trends in Food Science and Technology 19:265274.Google Scholar
60Pugliese, P., Zanasi, C., Atallah, O., and Cosimo, R. 2012. Investigating the interaction between organic and local foods in the Mediterranean: The Lebanese organic consumer's perspective. Food Policy 39:112.Google Scholar
61Jarosz, L. 2008. The city in the country: Growing alternative food Networks in Metropolitan areas. Journal of Rural Studies 24:231244.Google Scholar
62Garnett, T. 2011. Where are the best opportunities for reducing greenhouse gas emissions in the food system (including the food chain)? Food Policy 36:S23S32.Google Scholar
63Infante Amate, J. and González de Molina, M. 2013. ‘Sustainable de-growth’ in agriculture and food: An agro-ecological perspective on Spain's agri-food system (year 2000). Journal of Cleaner Production 38:2735.CrossRefGoogle Scholar
64MAGRAMA. 2013. Inventario de Gases de Efecto Invernadero en España. Edición 2013 (serie 1990–2012). Ministerio de Agricultura, Alimentación y Medio Ambiente. Available at Web site http://www.magrama.gob.es/es/calidad-y-evaluacion-ambiental/temas/sistema-espanol-de-inventario-sei-/Sumario_inventario_GEI_Espa%C3%B1a_-_Serie_1990-2011_tcm7-1741.pdf (accessed May 20, 2014).Google Scholar
65Foster, C., Green, K., Bleda, M., Dewick, P., Evans, B., Flynn, A., and Mylan, J. 2006. Environmental Impacts of Food Production and Consumption: A Report to the Department of Environment, Food and Rural Affairs. Manchester Business School, Defra, London.Google Scholar
66European Commission. 2010. Europe 2020: A Strategy for Smart, Sustainable and Inclusive Growth. European Commission, Brussels. Available at Web site http://www.efesme.org/europe-2020-a-strategy-for-smart-sustainable-and-inclusive-growth (accessed April 17, 2013)Google Scholar
67Edwards-Jones, G., Milà i Canals, Ll., Hounsome, N., Truninger, M., Koerber, G., Hounsome, B., Cross, P., York, E., Hospido, A., Plassmann, K., Harris, I.M., Edwards, R.T., Day, G.A.S., Deri Tomos, A., Cowell, S., and Jones, D.L. 2008. Testing the assertion tha ‘local food is best’: The challenges of an evidence-based approach. Trends in Food Science and Technology 19:265274.Google Scholar
68McMichael, A., Powls, J.W., Butler, C.D., and Uay, R. 2007. Food, livestock production, energy, climate change, and health. In: Energy and Health, vol. 370. Available at Web site www.thelancet.com (accessed April 12, 2013).Google Scholar
69Duram, L. and Oberholtzer, L. 2010. A geographic approach to place and natural resource use in local food systems. Renewable Agriculture and Food Systems 25(2):99108.Google Scholar