[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5713/ajas.15.0796

Assessment of the Contribution of Poultry and Pig Production to Greenhouse Gas Emissions in South Korea Over the Last 10 Years (2005 through 2014)

Boontiam, Waewaree (Department of Agricultural Biotechnology, Research Institute for Agricultural and Life Sciences, Seoul National University)
Shin, Yongjin (Department of Agricultural Biotechnology, Research Institute for Agricultural and Life Sciences, Seoul National University)
Choi, Hong Lim (Department of Agricultural Biotechnology, Research Institute for Agricultural and Life Sciences, Seoul National University)
Kumari, Priyanka (Department of Agricultural Biotechnology, Research Institute for Agricultural and Life Sciences, Seoul National University)

Publication Information

Asian-Australasian Journal of Animal Sciences / v.29, no.12, 2016 , pp. 1805-1811 More about this Journal

Abstract

The goal of this study was to estimate the emissions of greenhouse gases (GHG), namely methane ( $CH_4$ ), nitrous oxide ( $N_2O$ ), and carbon dioxide ( $CO_2$ ) from poultry and pig production in South Korea over the last 10 years (2005 through 2014). The calculations of GHG emissions were based on Intergovernmental Panel on Climate Change (IPCC) guidelines. Over the study period, the $CH_4$ emission from manure management decreased in layer chickens, nursery to finishing pigs and gestating to lactating sows, but there was a gradual increase in $CH_4$ emission from broiler chickens and male breeding pigs. Both sows and nursery to finishing pigs were associated with greater emissions from enteric fermentation than the boars, especially in 2009. Layer chickens produced lower direct and indirect $N_2O$ emissions from 2009 to 2014, whereas the average direct and indirect $N_2O$ emissions from manure management for broiler chickens were 12.48 and $4.93Gg\;CO_2-eq/yr$ , respectively. Annual direct and indirect $N_2O$ emissions for broiler chickens tended to decrease in 2014. Average $CO_2$ emission from direct on-farm energy uses for broiler and layer chickens were 46.62 and $136.56Gg\;CO_2-eq/yr$ , respectively. For pig sectors, the $N_2O$ emission from direct and indirect sources gradually increased, but they decreased for breeding pigs. Carbon dioxide emission from direct on-farm energy uses reached a maximum of $53.93Gg\;CO_2-eq/yr$ in 2009, but this total gradually declined in 2010 and 2011. For boars, the greatest $CO_2$ emission occurred in 2012 and was $9.44Gg\;CO_2-eq/yr$ . Indirect $N_2O$ emission was the largest component of GHG emissions in broilers. In layer chickens, the largest contributing factor to GHG emissions was $CO_2$ from direct on-farm energy uses. For pig production, the largest component of GHG emissions was $CH_4$ from manure management, followed by $$CO_2$ $$$ emission from direct on-farm energy use and $CH_4$ enteric fermentation emission, which accounted for 8.47, 2.85, and $2.82Gg-CO_2/yr$ , respectively. The greatest GHG emission intensity occurred in female breeding sows relative to boars. Overall, it is an important issue for the poultry and pig industry of South Korea to reduce GHG emissions with the effective approaches for the sustainability of agricultural practices.

Keywords

Greenhouse Gases; Emission Intensity; Pig; Poultry; South Korea;

Citations & Related Records

Times Cited By KSCI : 5 (Citation Analysis)

Reference
Cited By KSCI

1	Dammgen, U., J. Schulz, H. K. Klausing, N. J. Hutchings, H.-D. Haenel, and C. Rosemann. 2012. Enteric methane emissions from German pigs. Landbauforschung 62:83-96.
2	Gerber, P. J., H. Steinfeld, B. Henderson, A. Mottet, C. Opio, J. Dijkman, A. Falcucci, and G. Tempio. 2013. Tackling climate change through livestock: A global assessment of emissions and mitigation opportunities. Food and Agriculture Organization of the United Nations (FAO), Rome, Italy.
3	Horndahl, T. 2008. Energy use in farm buildings. Faculty of Landscape Planning, Horticulture and Agricultural Science, Report 2008:8, Swedish University of Agricultural Sciences, Alnarp, Sweden.
4	IPCC (Intergovernmental Panel on Climate Change). 2006. 2006 IPCC Guidelines for National Greenhouse Gas Inventories http://www.ipcc-nggip.iges.or.jp/public/2006gl/vol4.html Accessed April 9, 2015.
5	Jorgensen, H., K. E. B. Knudsen, and P. K. Theil. 2011. Enteric methane emission from pigs. In: Planet Earth 2011 - Global Warming Challenges and Opportunities for Policy and Practice (Ed. E.G. Carayannis). InTech Europe, Rijeka, Croatia. pp. 605-623.
6	Ji, E. S. and K.-H. Park. 2012. Methane and nitrous oxide emissions from livestock agriculture in 16 local administrative districts of Korea. Asian Australas. J. Anim. Sci. 25:1768-1774. DOI
7	KFSS (Korean Feeding Standard for Swine). 2007. National Livestock Research Institute, RDA, Ministry of Agriculture and Forestry, Sejong, Korea.
8	KOSIS (Korean Statistical Information Service(. 2015. Korean Statistical Information Service http://kosis.kr/eng/statisticsList/ statisticsList_01List.jsp?vwcd=MT_ETITLE&parentId=A Accessed April 9, 2015.
9	Kyriazakis, I. 2011. Opportunities to improve nutrient efficiency in pigs and poultry through breeding. Animal 5:821-832. DOI
10	Lammers, P., M. Honeyman, J. Harmon, and M. Helmers. 2010. Energy and carbon inventory of Iowa swine production facilities. Agric. Syst. 103:551-561. DOI
11	Le Goff, G., S. Dubois, J. Van Milgen, and J. Noblet. 2002. Influence of dietary fibre level on digestive and metabolic utilisation of energy in growing and finishing pigs. Anim. Res. 51:245-259. DOI
12	Lee, H. J. and S. C. Lee. 2003. National methane inventory relevant to livestock enteric fermentation. J. Anim. Sci. Technol. 45:997-1006. DOI
13	Lim, B. R., G. J. Cho, Y. H. Jung, J. K. Yang, and S. K. Lee. 2011. Estimation of greenhouse gas emission from livestock wastewater treatment plants. J. Korea Soc. Waste Manag. 28:175-183.
14	MacLeod, M., P. Gerber, A. Mottet, G. Tempio, A. Falcucci, C. Opio, T. Vellinga, B. Henderson, and H. Steinfeld. 2013. Greenhouse gas emissions from pig and chicken supply chains-A global life cycle assessment. Food and Agriculture Organization of the United Nations (FAO), Rome, Italy.
15	Nam, J.-J., Y.-M. Yoon, Y.-H. Lee, K.-H. So, and C.-H. Kim. 2008. Life cycle assessment of greenhouse gas emissions from livestock and food wastes co-digestive biogas production system. Korean J. Environ. Agric. 27:406-412. DOI
16	National Research Council (NRC). 1998. Nutrient Requirements of Swine. 10th Ed. Natl. Acad. Press, Washington, DC, USA.
17	Philippe, F.-X., M. Laitat, J. Wavreille, B. Nicks, and J.-F. Cabaraux. 2015. Effects of a high-fibre diet on ammonia and greenhouse gas emissions from gestating sows and fattening pigs. Atmos. Environ. 109:197-204. DOI
18	Caro, D., S. J. Davis, S. Bastianoni, and K. Caldeira. 2014. Global and regional trends in greenhouse gas emissions from livestock. Clim. Change 126:203-216. DOI
19	Brander, M., A. Sood, C. Wylie, A. Haughton, and J. Lovell. 2011. Electricity-specific emission factors for grid electricity. Ecometrica, Edinburgh, United Kingdom. http:// ecometrica.com/assets//Electricity-specific-emission-factorsfor-grid-electricity.pdf Accessed June 11, 2015.
20	Campbell, R., M. Taverner, and D. Curic. 1985. Effects of sex and energy intake between 48 and 90 kg live weight on protein deposition in growing pigs. Anim. Prod. 40:497-503. DOI
21	Won, S., W. Cho, J. Lee, K. H. Park, and C. Ra. 2014. Data buildup for the construction of Korean specific greenhouse gas emission inventory in livestock categories. Asian Australas. J. Anim. Sci. 27:439-446. DOI
22	Portejoie, S., J.-Y. Dourmad, J. Martinez, and Y. Lebreton. 2004. Effect of lowering dietary crude protein on nitrogen excretion, manure composition and ammonia emission from fattening pigs. Livest. Prod. Sci. 91:45-55. DOI
23	Steinfeld, H., P. Gerber, T. Wassenaar, V. Castel, M. Rosales, and C. D. Haan. 2006. Livestock's long shadow: environmental issues and options Food and Agriculture Organization of the United Nations (FAO), Rome, Italy.
24	Tauson, A. H., A. Chwalibog, K. Jakobsen, and G. Thorbek. 1998. Pattern of protein retention in growing boars of different breeds, and estimation of maximum protein retention. Arch. Anim. Nutr. 51:253-262.
25	Varley, M. 2009. Taking control of feed conversion ratio. Pig Progress 25:22-23.