Opinion paper Special Issues

Food security as a function of Sustainable Intensification of Crop Production

  • Received: 26 January 2016 Accepted: 27 May 2016 Published: 25 January 2016
  • The challenge to eradicate hunger and establish food security across all its four pillars (availability, accessibility, health and safety, and continuity) is ongoing. The actual situation in global food production leads most of the attention to improving accessibility and safety of food, particularly to vulnerable populations. However, in view of the growth in demand, which includes changes in preferences for example towards food of animal origin, availability and continuity will play larger roles in future. Food production needs to increase over the coming decades at challenging rates, while facing problems of degradation and reduced availability of natural resources for production such as soil and water, and facing increasing challenges from climate change. The actual trends in yield development suggest that a simple gradual improvement of production within the existing concepts will not provide a sustainable or feasible solution, and that more fundamental changes in the agricultural production paradigm are required to face these future challenges. The Sustainable Intensification represents such a change in paradigm in which high production levels are combined with sustainability. The concept of sustainable intensification, the rationale for it and its functional elements, represented by Conservation Agriculture, are presented in this paper.

    Citation: Theodor Friedrich, Amir Kassam. Food security as a function of Sustainable Intensification of Crop Production[J]. AIMS Agriculture and Food, 2016, 1(2): 227-238. doi: 10.3934/agrfood.2016.2.227

    Related Papers:

  • The challenge to eradicate hunger and establish food security across all its four pillars (availability, accessibility, health and safety, and continuity) is ongoing. The actual situation in global food production leads most of the attention to improving accessibility and safety of food, particularly to vulnerable populations. However, in view of the growth in demand, which includes changes in preferences for example towards food of animal origin, availability and continuity will play larger roles in future. Food production needs to increase over the coming decades at challenging rates, while facing problems of degradation and reduced availability of natural resources for production such as soil and water, and facing increasing challenges from climate change. The actual trends in yield development suggest that a simple gradual improvement of production within the existing concepts will not provide a sustainable or feasible solution, and that more fundamental changes in the agricultural production paradigm are required to face these future challenges. The Sustainable Intensification represents such a change in paradigm in which high production levels are combined with sustainability. The concept of sustainable intensification, the rationale for it and its functional elements, represented by Conservation Agriculture, are presented in this paper.


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    [1] FAO (1996) The Rome Declaration on World Food Security; The World Food Summit. FAO, Rome. Available from: http://www.fao.org/wfs/
    [2] Royal Society (2009) Reaping the benefits: Science and the sustainable intensification of global agriculture. RS Policy Document 11/09. London.
    [3] Foresight (2011) The Future of Food and Farming. The Government Office for Science, London.
    [4] FAO (2011) Save and Grow: a policymaker’s guide to the sustainable intensification of smallholder crop production. FAO, Rome. 102.
    [5] MEA (2205) Millennium Ecosystem Assessment Reports. World Resource Institute. Washington D.C., Island Press.
    [6] Kassam A, Basch G, Friedrich T, et al. (2013) Sustainable soil management is more than what and how crops are grown. In: R. Lal and R. A. Stewart (Eds.). Principles of Soil Management in Agro-ecosystems. Advances in Soil Science. CRC Press.
    [7] WDR (2008) Agriculture for Development. World Development Report. Washington, DC: World Bank.
    [8] IAASTD (2009) Agriculture at the crossroads. International assessment of agricultural knowledge, science and technology for development. Island Press, Washington D.C.
    [9] Godfray C, Beddington JR, Crute IR, et al. (2010) Food security: The challenge of feeding 9 billion people. Science 327: 812-818. doi: 10.1126/science.1185383
    [10] FAO (2012) World Agriculture towards 2030/2050. The 2012 revision. N. Alexandratos and J. Bruinsma (eds). FAO, Rome.
    [11] FAO (2012) State of Food and Agriculture (SOFA) 2012 - Investing in agriculture for a better future. FAO, Rome.
    [12] FAO (2013) State of Food and Agriculture (SOFA) 2013 - Food systems for better nutrition. FAO, Rome.
    [13] FAO (2013) State of Food Insecurity (SOFI) 2013 – The multiple dimensions of food security, FAO, Rome.
    [14] FAO (2015) State of Food Insecurity (SOFI) 2015 - Meeting the 2015 international hunger targets: taking stock of uneven progress. FAO, Rome.
    [15] FAO (2015) State of Food and Agriculture (SOFA) 2015 - Social protection and agriculture: breaking the cycle of rural poverty. FAO, Rome.
    [16] UN (2015) Open Working Group proposal for Sustainable Development Goals, Full report of the Open Working Group of the General Assembly on Sustainable Development Goals, A/68/970. Available from: http://undocs.org/A/68/970
    [17] FAO (2014) Panorama de la Seguridad Alimentaria y Nutricional en América Latina y el Caribe 2014, FAO, Santiago de Chile
    [18] FAO (2014) Manual de Agricultura Climaticamente Intelligente. FAO, Rome.
    [19] The Global Food Security programme (2015) Extreme weather and resilience of the global food system Final Project Report from the UK-US Taskforce on Extreme Weather and Global Food System Resilience, The Global Food Security programme, UK. 20.
    [20] Winterbottom R, Reij C, Garrity D, et al. (2013) “Improving Land and Water Management.” Working Paper, Installment 4 of Creating a Sustainable Food Future. Washington, DC: World Resources Institute. 44.
    [21] Friedrich T (2007) Degradation of Natural Resources and Measures for Mitigation; in: APCAEM/MoA-PRC (Eds.): Handbook of the International Seminar on Enhancing Extension of Conservation Agriculture Techniques in Asia and the Pacific, Asian and Pacific Centre for Agricultural Engineering and Machinery (APCAEM) and Ministry of Agriculture of the Peoples Republic of China, Zhengzhou China, 24-26 Oct. 2007. 47-61.
    [22] SAI (2010) Water Conservation Technical Brief, TB 9 - Use of a conservation tillage system as a way to reduce water the footprint of crops; The SAI Platform, 22.
    [23] Montgomery D (2007) Dirt: The erosion of civilizations. University California Press, Berkeley and Los Angeles. 287.
    [24] Gibbs HK, Salmon JM (2015) Mapping the world’s degraded lands. Appl Geogr 57: 12-21. doi: 10.1016/j.apgeog.2014.11.024
    [25] Friedrich T, Kassam AH, Shaxson F (2009) Conservation Agriculture. In: Agriculture for Developing Countries. Science and Technology Options Assessment (STOA) Project. European Parliament. European Technology Assessment Group, Karlsruhe, Germany.
    [26] Kassam A, Friedrich T, Shaxson F, et al. (2009) The spread of Conservation Agriculture: Justification, sustainability and uptake. Int J Agric Sust 7: 292-320. doi: 10.3763/ijas.2009.0477
    [27] HLPE (2012) Climate change and food security. A report by the High Level Panel of Experts on Food Security and Nutrition of the Committee on World Food Security. Rome.
    [28] IPCC (2014) Climate Change 2014: Impacts, Adaptation, and Vulnerability. Part A: Global and Sectoral Aspects. Contribution of Working Group II to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change Field, C.B., V.R. Barros, D.J. Dokken, K.J. Mach, M.D. Mastrandrea, T.E. Bilir, M. Chatterjee, K.L. Ebi, Y.O. Estrada, R.C. Genova, B. Girma, E.S. Kissel, A.N. Levy, S. MacCracken, P.R. Mastrandrea, and L.L. White (eds.). Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1132.
    [29] FAO (2008) State of Food and Agriculture (SOFA) 2008 - Biofuels: prospects, risks and opportunities. FAO, Rome.
    [30] Haugen-Kozyra K, Goddard T (2009) Conservation agriculture protocols for green house gas offsets in a working carbon markets. Paper presented at the IV World Congress on Conservation Agriculture, 3-7 February 2009, New Delhi, India.
    [31] Corsi S, Friedrich T, Kassam A, et al. (2012) Soil Organic Carbon Accumulation and Greenhouse Gas Emission Reductions from Conservation Agriculture: A literature review, Integrated Crop Management Vol.16. FAO, Rome. 101.
    [32] FAO (2014) Agricultura Familiar en América Latina y el Caribe: Recomendaciones de Política; S. Salcedo y L. Guzmán (eds.). FAO, Chile.
    [33] FAO (2015) Save and Grow in practice: maize, rice and wheat. FAO, Rome.
    [34] 33. Kassam A, Friedrich T (2012) An ecologically sustainable approach to agricultural production intensification: Global perspectives and developments. Field Actions Sci Rep Special Issue 6.
    [35] FAO. What is CA? Conservation Agriculture Website of FAO. 2013. Available from: www.fao.org/ag/ca/1a.html
    [36] Saturnino HM, Landers JN (2002) The Environment and Zero Tillage; APDC-FAO, Brasilia, Brazil UDC 504:631/635, CDD 631.521
    [37] Baig MN, Gamache PM (2009) The Economic, Agronomic and Environmental Impact of No-Till on the Canadian Prairies. Alberta Reduced Tillage Linkages. Canada. 134.
    [38] Lindwall CW, Sonntag B (Eds) (2010) Landscape Transformed: The History of Conservation Tillage and Direct Seeding. Knowledge Impact in Society. Saskatoon: University of Saskatchewan. 219.
    [39] Mello I, van Raij B (2006) No-till for sustainable agriculture in Brazil. Proc World Assoc Soil Water Conserv P1: 49-57.
    [40] Kassam A, Friedrich T, Derpsch R, et al. (2015) Overview of the Worldwide Spread of Conservation Agriculture. Field Actions Sci Rep 8.
    [41] FAO. AquaStat: CA Adoption Worldwide. 2016. Available from: www.fao/ag/ca/6c.html
    [42] Gonsalves J, Campilan D, Smith G, Bui VL, Jimenez FM (Eds.) (2015) Towards Climate Resilience in Agriculture for Southeast Asia: An overview for decision-makers. Hanoi, Vietnam: International Center for Tropical Agriculture (CIAT). CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS). 450.
    [43] FAO (2010) An international consultation on integrated crop-livestock systems for development - The way forward for sustainable production intensification; Integrated Crop Management Vol.13. FAO, Rome. 63.
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