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Comparative environmental impact assessments of green food certified cucumber and conventional cucumber cultivation in China

Published online by Cambridge University Press:  29 May 2017

Fang Wang
Affiliation:
College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China
Yuexian Liu*
Affiliation:
College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China
Xihui Ouyang
Affiliation:
Beijing Green food office, Beijing Municipal Bureau of Agriculture, Beijing 100029, China
Jianqiang Hao
Affiliation:
Beijing Green food office, Beijing Municipal Bureau of Agriculture, Beijing 100029, China
Xiaosong Yang
Affiliation:
College of Resources and Environment, University of Chinese Academy of Sciences, Beijing 100049, China
*
*Corresponding author: [email protected]

Abstract

The need to ensure food safety has been recognized in China and the ‘Green Food’ system is used to restrict the use of chemical fertilizers and pesticides in its certified products. There has been limited study of the environmental impacts associated with the production of green food certified (GFC) products in China. In this study, life cycle assessment was used to evaluate environmental impacts of GFC cucumber cultivated under a greenhouse system in the suburbs of Beijing relative to conventional cultivation (CON), with the aim of identifying the key areas of potential environmental burden in cucumber cultivation. Eight environmental impact categories are considered, including global warming potential, energy depletion (ED), water depletion, acidification potential, aquatic eutrophication (AEU), human toxicity (HT), aquatic eco-toxicity (AET) and soil eco-toxicity (SET). Results showed that the environmental index of the GFC cucumber system was higher than that of the CON cucumber system. SET, EU and ED were identified as the main potential environmental impacts in cucumber systems, largely caused by fertilizer use on the farm. The potentials of HT and AET in GFC cucumber were lower than those in the CON system, mainly due to the reduced use of chemical pesticides. The agricultural input of plastics was the main contributor to energy depletion in both cucumber cultivation systems. Potential approaches to mitigate the environmental impacts of cucumber cultivation include increasing the fertilizer use efficiency, avoiding use of animal manure with high heavy metal content and recycling of plastics under the GFC cultivation system.

Type
Research Paper
Copyright
Copyright © Cambridge University Press 2017 

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References

Atafar, Z., Mesdaghinia, A., and Nouri, J. 2010. Effect of fertilizer application on soil heavy metal concentration. Environmental Monitoring and Assessment 160:8389.Google Scholar
Bai, L.Y., Zheng, X.B., Li, L.F., Pen, C., and Li, S.H. 2010. Effects of land use on heavy metal accumulation in soils and source analysis. Scientia Agriculture Sinica 43(1):96104.Google Scholar
Baumann, H. and Tillman, A.M. 2004. The Hitch Hiker's guide to LCA. In: An Orientation in Life Cycle Assessment Methodology and Application. Studentlitteratur, Lund, 543 p. ISBN 9144023642.Google Scholar
Biswas, W.K., Graham, J., Kerry, K., and John, M.B. 2010. Global warming contributions from wheat, sheep meat and wool production in Victoria, Australia—a life cycle assessment. Journal of Cleaner Production 18(14):13861392.Google Scholar
Cellura, M., Longo, S. and Mistretta, M. 2012. Life Cycle Assessment (LCA) of protected crops: An Italian case study. Journal of Cleaner Production 28, 5662.Google Scholar
Chen, L.H., Ni, W.Z., Li, X.L., and Sun, J.B. 2009. Investigation of heavy metal concentrations in commercial fertilizers commonly-used. Journal of Zhejiang Sci-Tech University 26(2): 2630.Google Scholar
Chinese Green Food Development Center, CGFDC 2015. The status of Green food certified products development in China. Available at Web site http://www.greenfood.org.cn/zl/tjnb/lssptjnb/201610/t20161012_5302734.htmGoogle Scholar
Duan, N. 2007. Fertilizer Enterprise Cleaner Production Audit Guidelines. Xinhua Press, Beijing, p. 3340.Google Scholar
Erickson, J.E., Cisar, J.L., Volin, J.C., and Snyder, G.H. 2001. Comparing nitrogen runoff and leaching between newly established St. Augustinegrass Turf and an alternative residential landscape. Crop Science 41:18891895.Google Scholar
Finnveden, G. and Potting, J. 1999. Eutrophication as an impact category. International Journal of Life Cycle Assessment 4(6):311.Google Scholar
Flessa, H., Ruser, R., Dorsch, P., Kamp, T., Jimenez, M.A., Munch, J.C., and Beese, F. 2002. Integrated evaluation of GHG emissions (CO2, CH4, and N2O) from two farming systems in southern Germany. Agriculture, Ecosystems and Environment 91, 175189.Google Scholar
Galloway, J.N., Schlesinger, W.H., Levy, H.I., Michaels, A., and Schnoor, J.L. 1995. Nitrogen fixation: Anthropogenic enhancement environmental response. Glob. Bio-geochem. Cycles 9:235252.Google Scholar
Guinée, J.B., Gorrée, M., Heijungs, R., Huppes, G., Kleijn, R., de Koning, A., WegenerSleeswijk, A., Suh, S., Udo des Heas, H., Bruijn, H., Duin, R.V., and Huijbregts, M.A.J. 2002. Handbook on the Life Cycle Assessment. Operational Guide to the IsoStandards. Book Series: Eco-efficiency in Industry and Science, Vol. 7. KluwerAcademic Publishers, Dordrecht, the Netherlands.Google Scholar
Gündogmus, E. 2006. Energy use on organic farming: A comparative analysis on organic versus conventional apricot production on small holdings in Turkey. Energy Conversion and Management 47(18–19), 33513359.Google Scholar
Hauschild, M. and Wenzel, H. 1998. Environmental assessment of products. In: M. Hauschild and H. Wenzel (eds). Scientific Background. Vol. 2. Chapman and Hall, London, p. 565.Google Scholar
He, X.Q., Qiao, Y.H., Liu, Y.X., Dendler, L., Yin, C., and Martin, F. 2016. Environmental Impact Assessment of Organic and Conventional Tomato Production in Urban Greenhouses of Beijing City, China. Journal of Cleaner Production, In Press.Google Scholar
Hoeppner, J.W., Entz, M.H., McConkey, B.G., Zentner, R.P., and Nagy, C.N. 2006. Energy use and efficiency in two Canadian organic and conventional crop production systems. Renewable Agriculture and Food Systems 21, 6067.Google Scholar
Huang, Z.P., Xu, B., Zhang, K.Q., and Yang, X.C. 2007. Accumulation of heavy metals in the f our years ‘continual swine manure-applied greenhouse soils. Transactions of the CSAE 23(11):239244. (in Chinese with English abstract)Google Scholar
Huijbregts, M.A.J. 2008. Normalisation in product life cycle assessment: An LCA of the global and European economic systems in the year 2000. Science of the Total Environment 390:227240.Google Scholar
Huijbregts, M.A.J., Thissen, U., Guinee, J.B., Jager, T., Kalf, D., Van de Meent, D., Ragas, A.M.J., Wegener, S.A., and Reijnders, L. 2000. Priority assessment of toxic substances in life cycle assessment. Part I: Calculation of toxicity potentials for 181 substances with the nested multi-media fate, exposure and effects model USESLCA. Chemosphere 41:541573.Google Scholar
Jager, D.T. and Visser, C.J.M. 1994. Uniform System for the Evaluation of Substances (USES). Version 1.0. Ministry of Housing, The Hague.Google Scholar
Kaltsas, A.M., Mamolos, A.P., Tsatsarelis, C.A., Nanos, G.D., and Kalburtji, K.L. 2007. Energy budget in organic and conventional olive groves. Agriculture, Ecosystems and Environment 122(2):243251.Google Scholar
Knudsen, 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
IPCC 2014. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, UK.Google Scholar
Liang, L. 2009. Environmental Impact Assessment of Circular Agriculture Based on Life Cycle Assessment: Methods and Case Studies. China Agricultural University Press, Beijing, p. 1639.Google Scholar
Liu, Y., Langer, V., Høgh-Jensen, H., and Egelyng, H. 2010. Energy use in organic, green and conventional pear producing systems– Cases from China. Journal of Sustainable Agriculture 34(6):630646.Google Scholar
Lu, W. 2005. Trade and Environment Dimensions in the Food and Food Processing Industries in Asia and the Pacific, A Country Case Study of China. Department of Agricultural Economics, Zhejiang University, Hangzhou.Google Scholar
Lu, S.C., Chen, Q., Zhang, F.S., and Jia, W.Z. 2008. Analysis of nitrogen input and soil nitrogen load in orchards of Hebei province. Plant Nutrition and Fertilizer Science 14(5):858865.Google Scholar
Marigni, M., Rossier, D., Crettaz, P., and Jolliet, O. 2002. Life cycle impact assessment of pesticides on human health and ecosystems. Agriculture, Ecosystems and Environment 93:379392.Google Scholar
McPharlin, I.R., Aylmore, P.M., and Jeffery, R.C. 1995. Nitrogen requirements of lettuce under sprinkler irrigation and trickle fertigation on a Spear wood sand. Journal of Plant Nutrition 18:219241.Google Scholar
Milà i Canals, L., Burnip, G.M., and Cowell, S.J. 2006. Evaluation of the environmental impacts of apple production using Life Cycle Assessment (LCA): Case study inNew Zealand. Agriculture, Ecosystems & Environment 114:226238.Google Scholar
Ministry of Agriculture 2013. Green Food-Fertilizer application guideline. (NY/T 394-2013), China Standards Press, Beijing.Google Scholar
Olesen, J.E., Schelde, K., Weiske, A., Weisbjerg, M.R., Asman, W.A.H., and Djurhuus, J. 2006. Modelling greenhouse gas emissions from European conventional and organic dairy farms. Agriculture, Ecosystems and Environment 112:200220.Google Scholar
Pan, X., Chen, L.K., Bu, Y.Q., et al. 2012. Effects of livestock manure on distribution of heavy metals and antibiotics in soil profiles of typical vegetable fields and orchards. Journal of Ecology and Rural Environment 28(5):518525.Google Scholar
Paull, J. 2008. The greening of China's food-Green Food, Organic Food, and Eco-labelling. Sustainable Consumption and Alternative Agri-Food Systems Conference. Liege University, Arlon, Belgium, p. 114.Google Scholar
Pimentel, D., Berardi, G., and Fase, S. 1983. Energy efficiency of farming systems: Organic and conventional agriculture. Agriculture, Ecosystems and Environment 9(4):359372.Google Scholar
Power, J.F. and Schepers, J.S. 1989. Nitrate contamination of groundwater in North America. Agriculture, Ecosystems & Environment 26(3–4):165187.Google Scholar
Ru, S.H., Zhang, G.Y., Sun, S.Y., Wang, L., and Geng, N. 2006. Characteristics and regularity of heavy metals Cu, Zn, Pb, Cd accumulation in different vegetables [J]. Acta Agriculturae Boreali-Sinica, 14691473.Google Scholar
Sanders, R. 2006. Organic agriculture in China: Do property rights matter? Journal of Comtemporary China 15(46):113132.Google Scholar
Scott, S., Si, Z., Schumilas, T., and Chen, A. 2014. Contradictions in state- and civil society-driven developments in China's ecological agriculture sector. Food Policy 45:158166.Google Scholar
The National Agricultural Technology Extension Service Center 1999. China organic fertilizer nutrients [M]. Agricultural Press, Beijing, China. p. 24200.Google Scholar
Torrellas, M., Antón, A., López, J.C., Baeza, E.J., Parra, J.P., Munoz, P., and Montero, J.I. 2012. LCA of a tomato crop in a multi-tunnel greenhouse in Almeria. International Journal of Life Cycle Assessment 17:863875.Google Scholar
Van Calker, K.J., Berentsen, P.B.M., de Boer, I.M.J., Giesen, G.W.J., and Huirne, R.B.M. 2004. An LP-model to analyze economic and ecological sustainability on Dutch dairy farms: Model presentation and application for experimental farm “de Marke”. Agricultural Systems 82:139160.Google Scholar
Wang, M. and Li, S.T. 2014. Heavy metals in fertilizers and effect of the fertilization on heavy metal accumulation in soils and crops. Plant Nutrition and Fertilizer Science (2):466480.Google Scholar
Wang, M.X., Wu, W.L., Liu, W.N., and Bao, Y.H. 2007. Life cycle assessment of the winter wheat-summer maize production system on the North China Plain. International Journal of Sustainable World 14:400407.Google Scholar
Yan, F., Zou, Z.R., Dong, J., Li, J., Zhang, Z.X., and Wang, Y. 2009. Effects of different fertilization treatment on yield and quality of cucumber in plastics greenhouse. Acta Agriculture Boreali-occidentalis Sinica 18(5):272275, 289.Google Scholar
Yang, J.S. 2006. Economic Studies on the Production and Consumption of Safe Vegetables. China Agricultural Press, Beijing (in Chinese, An Quan Shu Cai Sheng Chan Yu Xiao Fei De Jing Ji Xue Yang Jiu).Google Scholar
Yu, X. 2012. Productivity, efficiency and structural problems in Chinese dairy farmers. China Agriculture Economic Review 4(2):168175.Google Scholar
Yu, J.X., Liu, Y.F., Zhong, X.L., and Yao, J. 2009. Evaluation method of eutrophication in Poyang Lake and its leading factors. Acta Agriculture Jiangxi 21(4):25128.Google Scholar
Yu, X.H., Gao, Z.F., and Zeng, Y.C. 2014. Willing to pay for the “Green Food” in China. Food Policy 45:8087.Google Scholar
Zhang, W.L., Tian, Z.X., Zhang, N., and Li, X.Q. 1995. Investigation of nitrate pollution in ground water due to nitrogen fertilization in agricultural in North China. Plant Nutrition and Fertilizer Science 1(2):8087.Google Scholar
Zhang, W.L., Tian, Z.X., Zhang, N., and Li, X.Q. 1996. Nitrate pollution of groundwater in northern China. Agriculture Ecosystems & Environment 59:223.Google Scholar
Zhang, Y.S., Luan, S.J., Chen, L.L., and Shao, M. 2011. Estimating the volatilization of ammonia from synthetic nitrogenous fertilizers used in China. Journal of Environmental Management 92(2011):480493.Google Scholar
Zhang, L.D., Gao, L.H., Zhang, L.X., Wang, S.Z., Sui, X.L., and Zhang, Z.X. 2012. Alternate furrow irrigation and nitrogen level effects on migration of water and nitrate-nitrogen in soil and root growth of cucumber in solar-greenhouse. Scientia Horticulture 138:4349.Google Scholar
Zou, G.Y., Yang, Z.Y., Tao, A.Z., and Wang, M.J. 2004. Study on nutrient uptake by different vegetable crops with high input of organic fertilizer. Southwest China Journal of Agricultural Sciences 17:227229.Google Scholar