Vulnerability of Indian Agriculture to Climate Change: A Study of the Himalayan Region State
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Vulnerability of Indian Agriculture to Climate Change: A Study of the Himalayan Region State

Authors: Rajendra Kumar Isaac, Monisha Isaac

Abstract:

Climate variability and changes are the emerging challenges for Indian agriculture with the growing population to ensure national food security. A study was conducted to assess the Climatic Change effects in medium to low altitude areas of the Himalayan region causing changes in land use and cereal crop productivity with the various climatic parameters. The rainfall and temperature changes from 1951 to 2013 were studied at four locations of varying altitudes, namely Hardwar, Rudra Prayag, Uttar Kashi and Tehri Garwal. It was observed that there is noticeable increment in temperature on all the four locations. It was surprisingly observed that the mean rainfall intensity of 30 minutes duration has increased at the rate of 0.1 mm/hours since 2000. The study shows that the combined effect of increasing temperature, rainfall, runoff and urbanization at the mid-Himalayan region is causing an increase in various climatic disasters and changes in agriculture patterns. A noticeable change in cropping patterns, crop productivity and land use change was observed. Appropriate adaptation and mitigation strategies are necessary to ensure that sustainable and climate-resilient agriculture. Appropriate information is necessary for farmers, as well as planners and decision makers for developing, disseminating and adopting climate-smart technologies.

Keywords: Climate variability, agriculture, land use, mitigation strategies.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1129261

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References:


[1] IPCC (2007a) Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (Solomon, S; Qin, D; Manning, M; Chen, Z; Marquis, M; Averyt, KB; Tignor, M; Miller, HL (eds)). Cambridge and New York: Cambridge University Press.
[2] Pratap Singha,*, Lars Bengtssonb(2005)Impact of warmer climate on melt and evaporation for the rainfed, snowfed and glacierfed basins in the Himalayan region Journal of Hydrology 300 (2005) 140–154.
[3] International Centre for Integrated Mountain Development (2009). The Changing Himalayas GPO Box 3226, Kathmandu, Khumaltar, Lalitpur, Nepal Tel +977-1-5003222.
[4] IPCC (2007b) Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (Parry, ML; Canziani, OF; Palutikof, JP; van der Linden, PJ; Hanson, CE (eds)). Cambridge: Cambridge University Press.
[5] Du, MY; Kawashima, S; Yonemura, S; Zhang, XZ; Chen, SB (2004) ‘Mutual influence between human activities and climate change in the tibetan plateau during recent years’. Global and Planetary Change 41: 241-249.
[6] Isaac R.K. and Isaac Monisha (2016). Climatic changes and their effect in Himalayan region. Debris flows: risks, forecast, protection: Materials of IV International Conference (Russia, Irkutsk – Arshan village (The Republic of Byriatia), September 6–10, 2016). – Irkutsk: Publishing House of Sochava Institute of Geography SB RAS, pp271-279.
[7] IPCC (2007b) Climate Change 2007: Impacts, Adaptation and Vulnerability. Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change (Parry, ML; Canziani, OF; Palutikof, JP; van der Linden, PJ; Hanson, CE (eds)). Cambridge: Cambridge University Press.
[8] Barnett, TP; Adam, JC; Lettenmaier, DP (2005) ‘Potential impacts of a warming climate on water availability in a snow-dominated region’. Nature 438(17): 303-309.
[9] Graham, LP; Hagemann, S; Jaun, S; Beniston, M (2007) ‘On interpreting hydrological change from regional climate models’. Climate Change: 81(supp1): 97-122.
[10] Wieczorek, G. F., 1996, Landslide triggering mechanisms, in Turner, A.K., and Schuster, R.L., eds., Landslides: Investigations and Mitigation: Transportation Research Board, Special Report 247, Chapter 4, p. 76–90.
[11] Mandal Sujit and Maiti Ramkrishna (2013). Assessing the triggering rainfall-induced landslip events in the shivkhola watershed of darjiling Himalaya, West Bengal. European Journal of Geography Volume 4, Issue 3: 21-37 October 2013.
[12] Uttarakhand at a Glance 2010-11, (2011). Directorate of Economics and Statistics 100/6, Neshvilla Road, Dehradun (Uttarakhand).
[13] Shrestha, A. B., Wake, C. P., Mayewski, P. A., and Dibb, J. E. (1999). Maximum temperature trends in the Himalaya and its vicinity: An analysis based on temperature records from Nepal for the period 1971-94. Journal of Climate 12, 2775-2787. 153.
[14] Cruz, RV; Harasawa, H; Lal, M; Wu, S; Anokhin, Y; Punsalmaa, B; Honda, Y; Jafari, M; Li, C; Huu, NN (2007) ‘Climate change 2007: Impacts, adaptation and vulnerability’. In Parry, ML; Canziani, OF; Palutikof, JP; van der Linden, PJ; Hanson, CE (eds) Contribution of Working Group II to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change, pp 469-506. Cambridge: Cambridge University Press.
[15] https://knoema.com/ICPS2015/crop-production-statistics-of-india-1999-2014?location=1006050 Accessed on 10/02/2017.