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Change and Adaptation in Socio-Ecological Systems

Climate Change, Social Changes, Technological Development

Ed. by Inostroza, Luis / Fürst, Christine

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2300-3669
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Climate change and socio-ecological transformation in high mountains: an empirical study of Garhwal Himalaya

Vishwambhar Prasad Sati
Published Online: 2015-12-17 | DOI: https://doi.org/10.1515/cass-2015-0005

Abstract

Mountain regions are highly vulnerable to climate change, as they are ecologically fragile, tectonically and seismically active, and geologically sensitive. The main objectives of this study are to examine socio-ecological transformations and to illustrate the major driving forces - climate change, education and waves of modern civilization - in the Garhwal Himalaya. Data on socio-ecological systems and their patterns of change were accumulated from primary and secondary sources and through participatory rural appraisal. We present a case study where household level surveys were conducted in two villages. A total of 37 households were surveyed. Additionally, marginal farmers and extension workers were interviewed. Questions on population, migration, cropping pattern and livestock were answered by the head of the surveyed households. Population size was decreasing due to out-migration. The whole Garhwal region experienced 15.3% out-migration, while migration from the two villages was observed at 50% during the period 1990-2014. Similarly, changes in land use and cropping patterns and in the livestock population were observed. There was a decrease in the extent of land under cereals (24%) and fruits (79%), a decrease in fruit production (75%), and a decrease in the number of livestock (76%). Climate change was observed as a major driver of the decrease in production and productivity of cereals and fruits, leading to land abandonment. Education, on the other hand, was a major driver of out-migration. Further, extreme events through climate change happened more frequently and changed the landscape. This study reveals that an increase in infrastructural facilities to create jobs and sustainable land management can control out-migration and can enhance land capability.

Keywords: Out-migration; land abandonment; land use pattern; cropping pattern; driving forces; fruit crops; Garhwal Himalaya

References

  • [1] FAO, Community based adaptation in action, a case study from Bangladesh, Project, 2008.Google Scholar

  • [2] UNEP, Environment for development, climate and trade policies in a post-2012 World, 2009.Google Scholar

  • [3] UNFCCC, Background paper on impacts, vulnerability and adaptation to climate change in Africa for the African Workshop on Adaptation Implementation of Decision 1/CP.10 of the UNFCCC, Accra, Ghana, 2006, 5-53.Google Scholar

  • [4] IPCC. 2001. Climate Change 2001: impacts, adaptation, and vulnerability. Contribution of working group II to the third assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge, UK.Google Scholar

  • [5] UNDP/UNEP, Poverty and climate change reducing the vulnerability of the poor through adaptation, UNDP/UNEP, 2005, 55-56.Google Scholar

  • [6] FAO, Impact of climate change, pests and diseases on food security and poverty reduction, Background Document of 31st Session of the Committee on World Food Security Rome, Italy, 2005, 2-9Google Scholar

  • [7] Desanker, P. V. Impacts of climate change in Africa. WWF Climate Change Programme, Berlin, Germany, 2002.Google Scholar

  • [8] Nelson, GC; Rosegrant, MW; Koo, J; Robertson, R; Sulser, T; Zhu, T; Claudia, et al., Climate change impact on agriculture and costs of adaptation. Washington, DC: International Food Policy Research Institute, 2009.Google Scholar

  • [9] Rakshit, S; Ewban, R; Bhandari, D. Agriculture and climate forecasting: In Schipper, ELE; Ayers, J; Reid, H; Hug, S; Rahman, A (eds) community-based adaption: scaling it up! 2014, 122-135. London, UK; Routledge.Google Scholar

  • [10] Littell, J.S.; Mckenzie, D; Kerns, B. K.; Cushman, S; Shaw, CG. Managing uncertainty in climate driven ecological models to inform adaptation to climate change, ‘Ecoshere 2 (9): art 2011, 102.Google Scholar

  • [11] Patz, J. A.; Compbell-Lendrum, D; Holloway, T; Fley, J. A. Impact of regional climate change on human health. Nature, 2005, 438 (7066), 310-317.Google Scholar

  • [12] Malik, S. M.; Awan, H; Khan, N. Mapping vulnerability to climate change and its repercussions on human health in Pakistan. Globalization and Health, 2012, 8, 31.Web of ScienceGoogle Scholar

  • [13] Parry, M. L.; Rosenzweig, C; Iglesias, A; Livermore, M; Fischer, G. Effects of climate change on global food production under SRES emissions and socio-economic scenarios’, Global Environmental Change, 2004, 14, 53-67.Google Scholar

  • [14] Mega, FJ: Silva, D. Dynamics adaption to maize and wheat production to climate change, Climate Change, 2009, 94, 143-156.Google Scholar

  • [15] Lobell, D.B; Gourdji, SM. The influence of climate change on global crop productivity. Plant Physiology, 2012, 160, 1686-1697.Google Scholar

  • [16] UNFAO. The state of food insecurity in the world: eradicating world hunger - key to achieving the Millennium Development Goals, Rome, Italy: Food and Agricultural Organization (FAO), 2005.Google Scholar

  • [17] Rowhani, P; Lobell, D; Linderman, M; and Romankutty, N. Climate variability and crop production in Tanzania. Agriculture and forest meteorology, 2011, 151, 449-460.Google Scholar

  • [18] ICIMOD. Background Note for Regional Meeting of Experts on Development of Micro Enterprises in Mountain Area 25-26 July, Unpublished Text, 2007.Google Scholar

  • [19] UNU project on sustainable mountain and forest development, UNU contribution to the Agenda 21, Chapter 13: Managing Fragile Ecosystems: Sustainable Mountain Development Retrieved from www. unu.edu/env/mountainsGoogle Scholar

  • [20] Ives, J. and Messerli, E.P. The Himalayan Dilemma: Reconciling Development and Conservation. Routledge, London, 1989.Google Scholar

  • [21] Sati, V. P. Towards Sustainable Livelihoods and Ecosystems in Mountain Regions, Springer Cham, Germany, 2014.Google Scholar

  • [22] Sati, V. P. Landscape vulnerability and rehabilitation issues: a study of hydropower projects in the Garhwal region, Himalaya, Natural Hazards. Vol. 75, 2014.Web of ScienceGoogle Scholar

  • [23] Sati, V. P. Natural Resource Conditions and Economic Development in the Uttaranchal Himalaya, India, Journal of Mountain Science, 2005, 2, 336-350.Google Scholar

  • [24] Renton, Alex et al. Suffering the Science: climate change, people and poverty, Oxfam briefing paper 130, 2009Google Scholar

  • [25] Dash S.K. and Hunt J.C. R., Variability of climate change in India, Current Science, 2007, 93, 782.Google Scholar

  • [26] Singh SP, Singh, Vishal, Skutsch Margaret. Rapid warming in the Himalayas: Ecosystem responses and development options. Climate and Development, 2010, 2, 3, 2010, 221-232Google Scholar

  • [27] Armando L (2014) Climate Change, Adaptation and Water in the Central Andes in Sanchis-Ibor, C.; Palau-Salvador, G. Mangue Alferez, I.; Martinez-Sanmartin, L.P. (Eds.) Irrigation, Society, Landscape. Tribute to Thomas F. Glick, Valencia, Universitat Politecnica de Valencia, 2014. doi: http://dx.doi.org/10.4995/ISL2014.2014.195CrossrefGoogle Scholar

  • [28] Vuille, M., Francou, B., Wagnon, P., Juen, I., Kaser, G., Mark, B. G. & Bradley, R. S. (2008): Climate change and tropical Andean glaciers: Past, present and future. Earth-Science Reviews, 89, 79-96.Web of ScienceGoogle Scholar

  • [29] Van der Hammen, T, Pabón, J D, Gutiérrez H, Alarcón J C. (2002). Cambio Global en los ecosistemas de alta montaña en Colombia. In: C. Castaño. (Ed.). Paramos Ecosistemas alto andinos de Colombia. Ministerio del Medio Ambiente /IDEAM / PNUD. Bogota.Google Scholar

  • [30] Rhoades, R. (2008): Disappearance of the glacier on mama cotacachi: Ethnoecological research and climate change in the Ecuadorian Andes. Pirineos, 37-50.Google Scholar

  • [31] Schulte, M., Magne, F., Torrico, A., Paz, L.& Cespedes, R. (1998). La Producción Agrícola en la Región Kallawaya. Instituto de Ecología, Universidad mayor de San Andrés. Offset Boliviana Ltda. EDOBOL Publisher, La Paz, Bolivia.Google Scholar

  • [32] Mittermeier, R.A., Gils; P.R.; Hoffman, M.; Pilgrim, J.;Brooks, T.; Mittermeier, C.G.; Lamoreaux, J.; Da Fonseca, G.A.B. (eds.), Hotspots Revisited. Earth’s Biologically Richest and Most Endnagered Terrestrial Ecoregions. 2004 USA: CEMEXGoogle Scholar

  • [33] Mehta, P. S., Negi K. S. & Ojha, S. N. Native Plant Genetic Resources and Traditional Foods of Uttarakhand Himalaya for sustainable food Security and Livelihood. Indian Journal of Natural Products and Resources, 2010, 1, 89-96.Google Scholar

  • [34] Altieri, M. A. (1995) Agro-ecology puts synergy to work to create selfsustaining agroecosystem. Ceres FAO Review 154, 27, 15-23.Google Scholar

  • [35] Ramakrishnan, P. S. & Saxena, K. G. Managing biodiversity for sustainable development in the Himalaya. In Ramakrishnan, PS; Purohit, AN; Saxena, KG; Rao, KS; Maikhuri, RK ed. Conservation and Management of Biological Resources in Himalaya, IBH, Oxford, 1996, 5-26.Google Scholar

  • [36] Das Anup, P.K. Ghosh, B.U. Choudhury, D.P. Patel, G.C. Munda, S.V. Ngachan and Pulakabha Chowdhury, (2006) Climate change in northeast India: recent facts and events-worry for agricultural management, ISPRS Archives XXXVIII-8/ W3 Workshop Proceedings: Impact of Climate Change on Agriculture.Google Scholar

  • [37] Das, P.J. and Goswami, D.C., (2003) Long-term variability of rainfall over northeast India. Indian Journal of Landscape Systems and Ecological Studies, 26(1):1-20. 8.Google Scholar

  • [38] Sati, V. P. 2014. Practices of Shifting Cultivation and its Implications in Mizoram, North-East India: A Review of Existing Research, Nature and Environment, Vol 19(2), Pp. 179-187, ISSN: 2321-810X (Print), 2321-8738 (Online), www.natureandenvironment.comGoogle Scholar

  • [39] Sati, V. P. Extreme Weather Related Disasters: A Case Study of Two Flashfloods Hit Areas of Badrinath and Kedarnath Valleys, Uttarakhand Himalaya, India, Journal of Earth Science and Engineering, 2013, 3, 562-568. Google Scholar

About the article

Received: 2015-02-01

Accepted: 2015-09-30

Published Online: 2015-12-17

Published in Print: 2015-01-01


Citation Information: Change and Adaptation in Socio-Ecological Systems, Volume 2, Issue 1, ISSN (Online) 2300-3669, DOI: https://doi.org/10.1515/cass-2015-0005.

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© 2015. This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License. BY-NC-ND 3.0

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