Open Access
Subscription Access
Characterizing Shifting Pattern of Disaster-Induced Death and Disaster Management Policies: A Regional Analysis from Odisha, India
A study was conducted to understand if the disaster death in Odisha, India across five categories, viz. tropical cyclone, lightning, heat wave, cold wave and extreme precipitation events underwent any significant change during 2001–14. It was based on timeseries data available at the National Data Portal of India. Results of the study suggest that the number of fatalities from sporadic meso-scale meteorological hazards like cyclones and heavy precipitation have drastically reduced due to better forecasting and effective evacuation strategies adopted by the Government. However, fatalities due to more frequent recurring extreme events, such as lightning and heat stress are on the rise. Male adults and middle-aged people (30–44 and 45–59 years respectively) constituted the most vulnerable groups affected by lightning and heat stress which account for maximum number of deaths in the state. Older population (especially older women) were more vulnerable towards cold wave due to reduced thermoregulatory mechanism. The finding is significant, because often deaths due to lightning injury, heat stress and cold wave either go unnoticed or are under-reported. We expect that the present study which focuses on gender and age disaggregated death would help in adopting more targeted mitigation or adaptation strategies in Odisha. The study also points out the need of a single and detailed spatio-temporal data infrastructure for all kinds of disaster deaths for more in-depth and insightful analysis.
Keywords
Disaster-Induced Death, Mitigation Strategies, Regional Analysis, Shifting Patterns.
User
Font Size
Information
- CRED, Natural Disasters 2017, Centre for Research on the Epidemiology of Disasters, Brussels, Belgium, 2017; https://cred.be/sites/default/files/adsr_2017.pdf
- Mahapatra, B., Walia, M. and Saggurti, N., Extreme weather events induced deaths in India 2001–2014: trends and differentials by region, sex and age group. Weather Climate Extrem., 2018, 21, 110–116.
- Ikefuji, M. and Horii, R., Natural disasters in a two-sector model of endogenous growth. J. Public Econ., 2012, 96, 784–796.
- Paprotny, D., Sebastian, A., Morales-Nápoles, O. and Jonkman, S. N., Trends in flood losses in Europe over the past 150 years. Nature Commun., 2018, 9.
- Spinoni, J., Naumann, G. and Vogt, J. V., Pan-European seasonal trends and recent changes of drought frequency and severity. Global Planet. Change, 2017, 148, 113–130.
- Forzieri, G. et al., Escalating impacts of climate extremes on critical infrastructures in Europe. Global Environ. Change, 2018, 48, 97–107.
- Mentaschi, L., Vousdoukas, M. I., Pekel, J. F., Voukouvalas, E. and Feyen, L., Global long-term observations of coastal erosion and accretion. Sci. Rep., 2018, 8, 1–11.
- Watts, N. et al., The lancet countdown: tracking progress on health and climate change. Lancet, 2017, 389, 1151–1164.
- Kapur, A., Vulnerable India: a Geographical Study of Disasters, SAGE Publications, 2010; https://doi.org/10.4135/9788132105428.
- Flatø, M., Muttarak, R. and Pelser, A., Women, weather and woes: the triangular dynamics of female-headed households, economic vulnerability and climate variability in South Africa. World Dev., 2017, 90, 41–62.
- Neumayer, E. and Plümper, T., The gendered nature of natural disasters: the impact of catastrophic events on the gender gap in life expectancy, 1981–2002. Ann. Assoc. Am. Geogr., 2007, 97, 551–566.
- Lass, W., Haas, A., Hinkel, J. and Jaeger, C., Avoiding the avoidable: Towards a European heat wave risk governance. Int. J. Disaster Risk Sci., 2011, 2, 1–14; https://doi.org/10.1007/s13753-0110001-z.
- Mishra, M., Analyzing the dynamics of social vulnerability to climate induced natural disasters in Orissa, India. Int. J. Soc. Sci., 2015, 4, 217.
- Chhotray, V. and Few, R., Post-disaster recovery and ongoing vulnerability: ten years after the super-cyclone of 1999 in Orissa, India. Global Environ. Change, 2012, 22, 695–702.
- Ray‐Bennett, N. S., Multiple disasters and policy responses in pre‐ and post‐independence Orissa, India. Disasters, 2009, 33, 274–290.
- Das, S., Economics of natural disasters in Odisha. In The Economy of Odisha, Oxford University Press, 2018, pp. 266–300; https://doi.org/10.1093/acprof:oso/9780199464784.003.0009.
- Pal, I., Ghosh, T. and Ghosh, C., Institutional framework and administrative systems for effective disaster risk governance – perspectives of 2013 cyclone Phailin in India. Int. J. Disaster Risk Reduct., 2017, 21, 350–359.
- SEOC, Situation Report on Extremely Severe Cyclonic Storm ‘FANI’, State Emergency Operation Centre, Bhubaneswar, 2019.
- Das, S., Television is more effective in bringing behavioral change: evidence from heat-wave awareness campaign in India. World Dev., 2016, 88, 107–121.
- Ray-Bennett, N. S., Disasters, deaths and the Sendai Goal One: lessons from Odisha, India. World Dev., 2018, 103, 27–39.
- Suar, D. and Kar, S., Social and behavioural consequences of the Orissa Supercyclone. J. Health Manage., 2005, 7, 263–275.
- Christian, P., Kandpal, E., Palaniswamy, N. and Rao, V., Safety nets and natural disaster mitigation: evidence from cyclone Phailin in Odisha. Climate Change, 2019.
- Walch, C., Evacuation ahead of natural disasters: evidence from cyclone Phailin in India and typhoon Haiyan in the Philippines. Geol. Geogr. Environ., 2018, 5(1), e00051; https://doi.org/ 10.1002/geo2.51.
- Yadav, D. K. and Barve, A., Analysis of socioeconomic vulnerability for cyclone-affected communities in coastal Odisha, India. Int. J. Disaster Risk Reduct., 2017, 22, 387–396.
- Borgerhoff Mulder, M., Msalu, L., Caro, T. and Salerno, J., Remarkable rates of lightning strike mortality in Malawi. PLOS ONE, 2012, 7, 8–11.
- Smith, P. J., Brown, S. and Dugar, S., Community-based early warning systems for flood risk mitigation in Nepal. Nat. Hazards Earth Syst. Sci., 2017, 17, 423–437.
- Bradshaw, S., Fordham, M., Women, girls and disasters: a review for DFID, 2013; https://gsdrc.org/document-library/women-girlsanddisasters-a-review-for-dfid/
- Cutter, S. L., The forgotten casualties redux: women, children, and disaster risk. Global Environ. Change, 2017, 42, 117–121.
- Lass, W., Haas, A., Hinkel, J. and Jaeger, C., Avoiding the avoidable: towards a European heat waves risk governance. Int. J. Disaster Risk Sci., 2011, 2, 1–14.
- Eklund, L. and Tellier, S., Gender and international crisis response: do we have the data, and does it matter? Disasters, 2012, 36, 589–608.
- Ray-Bennett, N., Caste, Class and Gender in Multiple Disasters: The Experiences of Women-Headed Household’s in an Oriya Village, India, VDM Verlag Dr Muller Aktiengesellschaft & Co. KG, Saarbrucken, 2009; ISBN 978363919379.
- Ray-Bennett, N. S., The influence of caste, class and gender in surviving multiple disasters: a case study from Orissa, India.Environ. Hazards, 2009, 8, 5–22.
- Selvi, S. and Rajapandian, S., Analysis of lightning hazards in India. Int. J. Disaster Risk Reduct., 2016, 19, 22–24.
- TOI, Odisha registers 31% decline in number of lightning deaths. Times of India, Bhubaneswar, July 2019.
- Singh, O. and Singh, J., Lightning fatalities over India: 1979–2011. Meteorol. Appl., 2015, 22, 770–778.
- Gouda, K. C., Sahoo, S. K., Samantray, P. and Himesh, S., Simulation of extreme temperature over Odisha during May 2015. Weather Climate Extrem., 2017, 17, 17–28.
- Singha, M., Odisha faces highest lightning strikes in country, but sees lowest deaths. Times of India, Bhubaneswar, September 2019.
- Barik, S., Odisha to plant palms to arrest lightning bolts. Hindu, Bhubaneswar, May 2018.
- Nageswararao, M. M., Sinha, P., Mohanty, U. C. and Mishra, S., Occurrence of more heat waves over the Central East Coast of India in the recent warming era. Pure Appl. Geophys., 2019, 177(2), 1143–1155; https://doi.org/10.1007/s00024-019-02304-2.
- Medina-Ramón, M. and Schwartz, J., Temperature, temperature extremes, and mortality: a study of acclimatisation and effect modification in 50 US cities. Occup. Environ. Med., 2007, 64, 827–833.
- Joe, L. et al., Mortality during a large-scale heat wave by place, demographic group, internal and external causes of death, and building climate zone. Int. J. Environ. Res. Public Health, 2016, 13(3), 299; https://doi.org/10.3390/ijerph13030299.
- Mora, C., Counsell, C. W. W., Bielecki, C. R. and Louis, L. V., Twenty-seven ways a heat wave can kill you: deadly heat in the era of climate change. Circ. Cardiovasc. Qual. Outcomes, 2017, 10.
- Ingole, V. et al., Socio-environmental factors associated with heat and cold-related mortality in Vadu HDSS, western India: a population-based case-crossover study. Int. J. Biometeorol., 2017, 61, 1797–1804.
- Murari, K. K. and Ghosh, S., Future heat wave projections and impacts. In Climate Change Signals and Response, Springer, Singapore, 2019, pp. 91–107.
- Jahn, M., Economics of extreme weather events: terminology and regional impact models. Weather Climate Extrem., 2015, 10, 29–39.
Abstract Views: 312
PDF Views: 130