Compartive life cycle assessment of mechanized and semi-mechanized methods of potato cultivation

Alireza Shahmohammadi , Hadi Veisi , Kouros Khoshbakht

Energy, Ecology and Environment ›› 2018, Vol. 3 ›› Issue (5) : 288 -295.

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Energy, Ecology and Environment ›› 2018, Vol. 3 ›› Issue (5) : 288 -295. DOI: 10.1007/s40974-018-0099-6
Original Article

Compartive life cycle assessment of mechanized and semi-mechanized methods of potato cultivation

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Abstract

Evaluating the environmental performance of production systems is necessary for the assessment of ecosystems from the perspective of sustainability. Life cycle assessment is a suitable method of evaluating the environmental impact of a product, process or activity by identifying, quantifying and assessing the resources expended and the emissions and waste released into the environment. The present study used life cycle assessment (LCA) of one ton of potatoes (Solanum tuberosum L.) from the boundary of a farm in Markazi province in Iran. The data were obtained from 120 questionnaires and include input sources from the cities of Arak and Shazand for semi-mechanized and traditional cultivation systems. Investigation of the environmental impact of potato cultivation was done using the LCA method and Simapro 8.0.4 software. It was estimated for abiotic depletion potential, global warming potential and ozone layer depletion potential. The results show that the semi-mechanized farming system has destructive effects on global warming (1.71 kgSbeq) and causes abiotic depletion (227.56 kgco2eq). The traditional cultivation method causes ozone layer depletion (0.00005 kgCFC-11) from diesel fuel consumption by water pumps. The strategies outlined in the alternative framework include replacement by renewable energy, ecological and agronomic pest control and optimization strategies such as development and improvement of machinery in conformity with international standards, training farmers to make optimal use of inputs and education to reduce damaging effects to the environment.

Keywords

Life cycle assessment / Abiotic depletion / Global warming / Ozone layer depletion

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Alireza Shahmohammadi, Hadi Veisi, Kouros Khoshbakht. Compartive life cycle assessment of mechanized and semi-mechanized methods of potato cultivation. Energy, Ecology and Environment, 2018, 3(5): 288-295 DOI:10.1007/s40974-018-0099-6

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Allen DT, Rosselot KS. Pollution prevention for chemical processes, 1997 Hoboken Wiley
[2]

Brentrup F, Küsters J, Lammel J, Kuhlmann H. Methods to estimate on-field nitrogen emissions from crop production as an input to LCA studies in the agricultural sector. Int J Life Cycle Assess, 2000, 5(6): 349-357

[3]

Brentrup F, Küsters J, Lammel J, Barraclough P, Kuhlmann H. Environmental impact assessment of agricultural production systems using the life cycle assessment (LCA) methodology II. The application to N fertilizer use in winter wheat production systems. Eur J Agron, 2004, 20(3): 265-279

[4]

Cederberg C, Mattsson B. Life cycle assessment of milk production—a comparison of conventional and organic farming. J Clean Prod, 2000, 8(1): 49-60

[5]

Chandra S, Ziemke J, Tie X, Brasseur G. Elevated ozone in the troposphere over the Atlantic and Pacific oceans in the Northern Hemisphere. Geophys Res Lett, 2004, 31(23): 1-4

[6]

Dekamin M, Veisi H, Safari E, Liaghati H, Khoshbakht K, Dekamin MG. Life cycle assessment for rainbow trout (Oncorhynchus mykiss) production systems: a case study for Iran. J Clean Prod, 2015, 91: 43-55

[7]

Erickson J, Cisar J, Volin J, Snyder G. Comparing nitrogen runoff and leaching between newly established St. Augustinegrass turf and an alternative residential landscape. Crop Sci, 2001, 41(6): 1889-1895

[8]

Fadaei A, Dehghani MH, Nasseri S, Mahvi AH, Rastkari N, Shayeghi M. Organophosphorous pesticides in surface water of Iran. Bull Environ Contam Toxicol, 2012, 88(6): 867-869

[9]

FAO The state of the world’s land and water resources for food and agriculture (SOLAW)—Managing systems at risk. Food and Agriculture Organization of the United Nations, 2011 London Rome and Earthscan
[10]

FAO (2014). http://www.fao.org/faostat/en/#data/QC/visualize
[11]

Ferreira T, Gonçalves DA. Crop-yield/water-use production functions of potatoes (Solanum tuberosum L.) grown under differential nitrogen and irrigation treatments in a hot, dry climate. Agric Water Manag, 2007, 90(1): 45-55

[12]

Gasol CM, Gabarrell X, Anton A, Rigola M, Carrasco J, Ciria P, Rieradevall J. Life cycle assessment of a Brassica carinata bioenergy cropping system in southern Europe. Biomass Bioenerg, 2007, 31(8): 543-555

[13]

Godard C, Boissy J, Suret C, Gabrielle B (2012) LCA of starch potato from field to starch production plant gate. In: Paper presented at the 8th international conference on LCA in the Agri-Food Sector, Saint-Malo, France
[14]

Goebes MD, Strader R, Davidson C. An ammonia emission inventory for fertilizer application in the United States. Atmos Environ, 2003, 37(18): 2539-2550

[15]

Guinée J. Handbook on life cycle assessment—operational guide to the ISO standards. Int J Life Cycle Assess, 2001, 6(5): 255

[16]

IPCC (2014) Climate change. Mitigation of climate change. In: Working Group III contribution to the fifth assessment report of the Intergovernmental Panel on Climate Change: Cambridge University Press
[17]

Iriarte A, Rieradevall J, Gabarrell X. Life cycle assessment of sunflower and rapeseed as energy crops under Chilean conditions. J Clean Prod, 2010, 18(4): 336-345

[18]

ISO, I 14040: Environmental management–life cycle assessment–principles and framework, 2006 London British Standards Institution
[19]

Jihad-e-Agriculture, Mo (2016) Annual agricultural statistics. Ministry of Jihad-e-Agriculture of Iran. http://arak.jkm.ir/index.php/page/v1.html
[20]

Kafilzadeh F, Shiva AH, Malekpour R, Azad HN. Determination of organochlorine pesticide residues in water, sediments and fish from Lake Parishan, Iran. World J Fish Mar Sci, 2012, 4(2): 150-154
[21]

Lægreid M, Bockman OC, Kaarstad O. Agriculture, fertilizers and the environment, 1999 Wallingford CABI Publishing
[22]

Madronich S, Granier C. Tropospheric chemistry changes due to increased UV-B radiation Stratospheric Ozone Depletion/UV-B Radiation in the Biosphere, 1994 Berlin Springer
[23]

Moudrý J, Jelínková Z, Jarešová M, Plch R, Moudrý J, Konvalina P. Assessing greenhouse gas emissions from potato production and processing in the Czech Republic. Outlook Agric, 2013, 42(3): 179-183

[24]

Nemecek T, Heil A, Huguenin O, Meier S, Erzinger S, Blaser S, Zimmermann A (2007) Life cycle inventories of agricultural production systems. Final Report Ecoinvent v2. 0 No, 15
[25]

Nemecek T, von Richthofen JS, Dubois G, Casta P, Charles R, Pahl H. Environmental impacts of introducing grain legumes into European crop rotations. Eur J Agron, 2008, 28(3): 380-393

[26]

Pishgar-Komleh S, Sefeedpari P, Rafiee S. Energy and economic analysis of rice production under different farm levels in Guilan province of Iran. Energy, 2011, 36(10): 5824-5831

[27]

Pishgar-Komleh S, Ghahderijani M, Sefeedpari P. Energy consumption and CO 2 emissions analysis of potato production based on different farm size levels in Iran. J Clean Prod, 2012, 33: 183-191

[28]

Rebitzer G, Ekvall T, Frischknecht R, Hunkeler D, Norris G, Rydberg T, Pennington DW. Life cycle assessment: part 1: framework, goal and scope definition, inventory analysis, and applications. Environ Int, 2004, 30(5): 701-720

[29]

Smil V. Energy in nature and society: general energetics of complex systems, 2008 Cambridge MIT press
[30]

Snyder C, Bruulsema T, Jensen T, Fixen P. Review of greenhouse gas emissions from crop production systems and fertilizer management effects. Agr Ecosyst Environ, 2009, 133(3): 247-266

[31]

Solomon S (2007) Climate change 2007-the physical science basis: working group I contribution to the fourth assessment report of the IPCC (Vol. 4): Cambridge University Press
[32]

Talebi K. Diazinon residues in the basins of Anzali Lagoon, Iran. Bull Environ Contam Toxicol, 1998, 61(4): 477-483

[33]

Tzilivakis J, Warner D, May M, Lewis K, Jaggard K. An assessment of the energy inputs and greenhouse gas emissions in sugar beet (Beta vulgaris) production in the UK. Agric Syst, 2005, 85(2): 101-119

[34]

van Dijk HF, Van Pul WAJ, De Voogt P. Fate of pesticides in the atmosphere: implications for environmental risk assessment, 1999 Dordrecht Kluwer Academic Publishers

[35]

van Oers L, Guinée J. The abiotic depletion potential: background, updates, and future. Resources, 2016, 5(1): 16

[36]

Williams AG, Audsley E, Sandars DL. Environmental burdens of producing bread wheat, oilseed rape and potatoes in England and Wales using simulation and system modelling. Int J Life Cycle Assess, 2010, 15(8): 855-868

[37]

Yousefi M, Khoramivafa M, Mondani F. Integrated evaluation of energy use, greenhouse gas emissions and global warming potential for sugar beet (Beta vulgaris) agroecosystems in Iran. Atmos Environ, 2014, 92: 501-505

[38]

Zaher U, Higgins S, Carpenter-Boggs L. Interactive life cycle assessment framework to evaluate agricultural impacts and benchmark emission reduction credits from organic management. J Clean Prod, 2016, 115: 182-190

[39]

Zangeneh M, Omid M, Akram A. A comparative study on energy use and cost analysis of potato production under different farming technologies in Hamadan province of Iran. Energy, 2010, 35(7): 2927-2933

Funding

Shahid Chamran University(12010)

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