Abstract
Climate change poses formidable challenge to the development of livestock sector in India. The anticipated rise in temperature between 2.3 and 4.8°C over the entire country together with increased precipitation resulting from climate change is likely to aggravate the heat stress in dairy animals, adversely affecting their productive and reproductive performance, and hence reducing the total area where high yielding dairy cattle can be economically reared. Given the vulnerability of India to rise in sea level, the impact of increased intensity of extreme events on the livestock sector would be large and devastating for the low-income rural areas. The predicted negative impact of climate change on Indian agriculture would also adversely affect livestock production by aggravating the feed and fodder shortages. The livestock sector which will be a sufferer of climate change is itself a large source of methane emissions, an important greenhouse gas. In India, although the emission rate per animal is much lower than the developed countries, due to vast livestock population the total annual methane emissions are about 9–10 Tg from enteric fermentation and animal wastes.
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References
ALGAS (1998) Asia-least cost gas abatement strategy: India. Asia Development Bank, Global Environment Facility, United Nations Development Programme, Manila, Philippines, p 238
Baker-Blocker A, Donohue TM, Maney KH (1977) Methane flux from wetland areas. Tellus 29:245–250
Balling RC Jr (1982) Weight gain and mortality in feedlot cattle as influenced by weather conditions: refinement and verification of statistical models. In Center for Agricultural Meteorology and Climatology Report 82–1. University of Nebraska-Lincoln, Lincoln, NE, USA, p 52
Bandyopadhyay TK, Goyal P, Singh MP (1996) Generation of methane from paddy fields and cattle in India, and its reduction at source. Atmos Environ 30(14):2569–2574
Basu AK, Bandhyopadhyay PK (2004) The effect of season on the incidence of ticks. Bull Anim Health Prod Afr 52(1):39–42
Beede DK, Collier RJ (1986) Potential nutritional strategies for intensively managed cattle during thermal stress. J Anim Sci 62:543–554
Blake DR (1984) Increasing concentrations of atmospheric methane, 1979–1983. Ph.D.thesis, University of California, Irvine, CA, p 213
CAST (2004) Climate change and greenhouse gas mitigation: challenges and opportunities for agriculture. Task Force Report 141, Council for Agricultural Sciences and Technology, USA, p 120
Clifford BC, Davies A, Griffith G (1996) UK climate change models to predict crop disease and pest threats. Asp Appl Biol 45:269–276
Cline WR (1992) The economics of global warming. Institute for International Economics, Washington, DC, p 399
Crutzen PJ, Aselmann I, Seiler W (1986) Methane production by domestic animals, wild ruminants, other herbivorous fauna and humans. Tellus 38B:271–284
CSO (2000) Compendium of environment statistics. Central Statistical Organisation, Ministry of Statistics and Programme Implementation, Govt. of India, p 306
De D, Singh GP (2001) Monensin enriches UMMP upplementation on in vitro methane production in crossbred calves. In: Proceedings of the X Animal Nutritional Conference (Abstract papers), Karnal, India, 2001, Animal Nutrition Society of India, National Dairy Research Institute, 161
Dinar A, Mendelsohn R, Evenson R, Parikh J, Sanghi A, Kumar K, McKinsey J, Lonergan S (eds) (1998) Measuring the impact of climate change on Indian agriculture. World Bank Technical Paper No. 402, World Bank, Washington DC, p 266
Dutt T, Taneja VK, Avtar Singh, Singh A (1992) Comfort zone for maximal milk production in crossbred cattle. Ind J Dairy Sci 45(3):119–122
Ehhalt DH (1974) The atmospheric cycle of methane. Tellus 26:58–70
Evenson RE (1999) Global and local implications of biotechnology and climate change for future food supplies. Proc Natl Acad Sci U S A 96(11):5921–5928. http://www.pnas.org/cgi/reprint/96/11/5921.pdf
FAOSTAT. Agricultural production database. Food and Agricultural Organisation. http://www.apps.fao.org
Garg A, Bhattacharya S, Shukla PR, Dadhwal VK (2001) Regional and Sectoral assessment of greenhouse gas emissions in India. Atmos Environ 35:2679–2695
Geevan CP, Dixit AM, Silori C (2003) Ecological economic analysis of grassland systems: resource dynamics and management challenges – Kachchh District (Gujarat). EERC Working paper Series CPR-5, Gujarat Institute of Desert Ecology, Bhuj-Kachchh, p 131. http://www.irade.res.in/eerc/pdf/CPR_FR_Geevan.pdf
Gibbs MJ, Johnson DE (1993) Livestock emissions. In: International Methane Emissions. US Environmental Protection Agency, Climate Change Division, Washington, DC, U.S.A.
GOI (2002) Report of the working group on animal husbandry & dairying for the tenth five year plan (2002–2007). Working Group Sr. No. 42/2001, Government of India, Planning Commission, p 214
Hahn GL (1999) Dynamic responses of cattle to thermal heat loads. J Anim Sci 77(2):10–20
Hahn GL, Becker BA (1984) Assessing livestock stress. Agric Eng 65:15–17
Hahn GL, Mader TL (1997) Heat waves in relation to thermoregulation, feeding behavior, and mortality of feedlot cattle. In: Proceedings 5th International Livestock Environment Symposium, Minneapolis, MN, pp 563–571
Hahn GL, Klinedinst PL, Wilhite DA (1992) Climate change impacts on livestock production and management. American Society of Agricultural Engineers, St. Joseph, MI, p 16
Hall WB, McKeon GM, Carter JO, Day KA, Howden SM, Scanlan JC, Johnston PW, Burrows WH (1998) Climate change and Queensland’s grazing lands, II: an assessment of the impact on animal production from native pastures. Rangeland J 20(2):177–205
Harmens H, Williams PD, Bambrick MT, Ashenden TW, Hopkins A (2001) Impacts of elevated atmospheric CO2 and temperature on a semi-natural grassland: interactions with management. Sci Total Environ (Special issue), Detecting Environmental Change Conference, July 2001, London http://www.epa.gov/ttn/chief/conference/ei10/ghg/scheehle.pdf
Hopkins A (2000) A review of grassland production and fertilizer response data with reference to the basis for management agreements. Technical Report, Project BD1438, Institute of Grassland and Environment Research, UK, p 45 plus appendices
IPCC (2001) Technical summary: contribution of Working Group I to the Third Assessment Report. Intergovernmental Panel on Climate Change, January 2001
Kale MM, Basu SB (1993) Effect of climate and breed on the milk production of crossbred cattle. Ind J Dairy Sci 46(3):114–118
Kaur H, Arora SP (1982) Influence of level of nutrition and season on the oestrus cycle rhythm and on fertility in buffaloes. Trop Agric 59(4):274–278
Klinedinst PL, Wilhite DA, Hahn GL, Hubbard KG (1993) The potential effects of climate change on summer season dairy cattle milk production and reproduction. Clim Change 23:21–36
Kulkarni AA, Pingle SS, Atakare VG, Deshmukh AB (1998) Effect of climatic factors on milk production in crossbred cows. Indian Vet J 75(9):846–847
Kumar S, Prasad KD, Deb AR (2004) Seasonal prevalence of different ectoparasites infecting cattle and buffaloes. BAU J Res 16(1):159–163
Lal SN, Verma DN, Husain KQ (1987) Effect of air temperature and humidity on the feed consumption, cardio respiratory response and milk production in Haryana cows. Indian Vet J 64(2):115–121
Lerner J, Matthews E, Fung I (1988) Methane emission from animals: a global high resolution database. Glob Biogeochem Cycles 2(2):139–156
Lonergan S (1998) Climate warming and India. In: Dinar A et al (eds) Measuring the Impact of Climate Change on Indian Agriculture. World Bank Technical Paper No. 402, Washington DC, pp 33–67
Mandal DK, Rao AVMS, Singh K, Singh SP (2002a) Effects of macroclimatic factors on milk production in a Frieswal herd. Indian J Dairy Sci 55(3):166–170
Mandal DK, Rao AVMS, Singh K, Singh SP (2002b) Comfortable macroclimatic conditions for optimum milk production in Sahiwal cows. J Appl Zool Res 13(2/3):228–230
McDowell RE (1972) Improvement of livestock production in warm climates. Freeman, San Francisco, CA, p 711
Mendelsohn R (2003) Assessing the market damages from climate change. In: Griffin JM (ed) Global climate change: the science, economics and politics. Edward Elgar, UK, pp 92–113
Mitra AP (ed) (1992) Greenhouse gas emissions in India: 1992, update, Report No.4, Council of Scientific and Industrial Research, New Delhi
Mitra AP (ed) (1996) Global change: greenhouse gas emissions in India. Report No. 10, Council of Scientific and Industrial Research, New Delhi
Moss AR (1994) Methane production by ruminants – literature review of I. Dietary manipulation to reduce methane production and II. Laboratory procedures for estimating methane potential of diets. Nutr Abstr Rev Ser B 64:786–806
Mosse D, Gupta S, Mehta M, Shah V, Rees J (2002) Brokered livelihoods: debt, labour migration and development in tribal western India. J Dev Stud 38(5):59–88
Nordhaus WD (1998) Revised estimates of the impacts of climate change, p 18, http://www.econ.yale.edu/~nordhaus/homepage/impacttables20122998.PDF
NRC (1996) Nutrient requirement of beef cattle. National Research Council, National Academy Press, Washington, DC
NRC (2001) Nutrient requirement of dairy cattle. National Research Council, National Academy Press, Washington, DC
Ralph W (1987) A simple model predicts an insect’s distribution. Rural Res 136:14–16
Ramarao D (1988) Seasonal indices and meteorological correlates in the incidence of foot-and-mouth disease in Andhra Pradesh and Maharashtra. Indian J Anim Sci 58(4):432–434
Reilly J (1996) Agriculture in a changing climate: impacts and adaptation. In: Watson RT, Zinyowera MC, Moss RH (eds) Climate Change 1995: impacts, adaptations, and mitigation of climate change: scientific-technical analyses, Contribution of Working Group II to the Second Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, pp 429–467
Rosenzweig C, Iglesias A (1998) The use of crop models for international climate change impact assessment. In: Tsuji GY, Hoogrnboom G, Thorton PK (eds) Understanding options for agriculture production. Kluwer, Dordrecht, The Netherlands, pp 267–292
Saseendran SA, Singh KK, Rathore LS, Singh SV, Sinha SK (2000) Effect of climate change on rice production in the tropical humid climate of Kerala, India. Clim Change 44:495–514
Scheehle E (2002) Emissions and projections of non CO2 GreenHouse gases from developing countries 1990–2020, p 73
Sharma SK, Singh GR, Pathak RC (1991) Seasonal contours of foot-and-mouth disease in India. Indian J Anim Sci 61(12):1259–1261
Sheppard JC, Westberg H, Hopper JF, Ganesan K, Zimmerman P (1982) Inventory of global methane sources and their production rates. J Geophys Res 87:1305–1312
Shinde S, Taneja VK, Singh A (1990) Association of climatic variables and production and reproduction traits in crossbreds. Indian J Anim Sci 60(1):81–85
Singh GP (1998) Methanogenesis and production of greenhouse gases under animal husbandry system. Final report A.P.Cess fund project, National Dairy Research Institute, Karnal, India
Singh GP (2001) Livestock production and environmental protection. In: Proc. X Animal Nutrition Conference, National Dairy Research Institute, Karnal, India, pp 211–221
Singh GP, Madhu Mohini (1999) Effect of different levels of monensin in diet on rumen fermentation, nutrient digestibility and methane production in cattle. Asian Aust J Anim Sci 12(8):1215–1221
Singh KB, Nauriyal DC, Oberoi MS, Baxi KK (1996) Studies on occurrence of clinical mastitis in relation to climatic factors. Ind J Dairy Sci 49(8):534–536
Singh AP, Singla LD, Singh A (2000) A study on the effects of macroclimatic factors on the seasonal population dynamics of Boophilus microplus infesting the crossbred cattle of Ludhiana district. Int J Anim Sci 15(1):29–31
Singhal KK, Madhu Mohini (2002) Uncertainty reduction in methane and nitrous oxide gases emission from livestock in India. Project report, Dairy Cattle Nutrition Division, National Dairy Research Institute, Karnal, India, p 62
Srivastava AK, Garg MR (2002) Use of sulfur hexafluroide tracer technique for measurement of methane emission from ruminants. Ind J Dairy Sci 55(1):36–39
Sutherst RW (1995) The potential advance of pest in natural ecosystems under climate change: implications for planning and management. In: Pernetta J, Leemans C, Elder D, Humphrey S (eds) Impacts of climate change on ecosystems and species: terrestrial ecosystems. IUCN, Gland, Switzerland, pp 83–98
Sutherst RW, Yonow T, Chakraborty S, O’Donnell C, White N (1996) A generic approach to defining impacts of climate change on pests, weeds and diseases in Australia. In: Bouma WJ, Pearman GI, Manning MR (eds) Greenhouse: coping with climate change. CSIRO, Melbourne, pp 281–307
Tailor SP, Nagda RK (2005) Conception rate in buffaloes maintained under subhumid climate of Rajasthan. Ind J Dairy Sci 58(1):69–70
UNEP (1989) Criteria for assessing vulnerability to sea level rise: a global inventory to high risk area. Delft Hydraulics, Delft, The Netherlands, p 51
USEPA (1994) International anthropogenic methane emission, EPA -230 R-93-010, Washington, DC
Wathes CM, Jones CDR, Webester AJF (1983) Ventilation, air hygiene and animal health. Vet Rec 113(24):554–559
West JW (1999) Nutritional strategies for managing the heat stressed dairy cow. J Anim Sci 77(Suppl. 2/J):21–35
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Sirohi, S., Michaelowa, A. Sufferer and cause: Indian livestock and climate change. Climatic Change 85, 285–298 (2007). https://doi.org/10.1007/s10584-007-9241-8
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DOI: https://doi.org/10.1007/s10584-007-9241-8