Climate
Gulf region climate projected too hot to inhabit
The Gulf region is projected to endure heatwaves challenging human survival and adaptability if climate change is left unchecked, as computed in an important study. The Intergovernmental Panel on Climate Change reports (IPCC) present evidence that increasing anthropogenic greenhouse gas concentrations are responsible for the Earth’s warming in recent decades. Jeremy Pal and Elfatih Eltahir, at MIT, present a study showing projections of regional climate patterns due to expected increases in temperature and discuss the possible impacts on human health and societies for the gulf and Arabian peninsula, a region already recording high temperatures. A regional climate model for Southwest Asia was customised using 3 IPPC global climate models allowing detailed representation of topography, coastlines, extreme climatic events, and physical processes.
The scientists considered both dry-bulb temperature (T) and wet-bulb temperature (TW); indices used to investigate the impacts of climate change on heat stress. TW is a combined measure of temperature and humidity, or `mugginess', and provides a physically based relationship to the human body's core temperature. The maxima values for T that humans can endure is arbitrarily set at 60°C, and values exceeding 50 °C have already been reached in parts of this region over the past 30 years. Similarly, the cut off threshold for TW that humans can endure is 35°C and values up to 31 °C these have already been reached in parts of this world. For some of the gulf coast locations, low-elevation areas close to sea level experience high T, and those near the coast see high humidity. The authors used two greenhouse gas concentration scenarios, based on IPPC trajectories, in their calculations to predict the impacts of future climate change on Southwest Asia: one representing business as usual scenario (no proactive strategies to limit greenhouse gas emissions (RCP8.5) and another which considers mitigation (RCP4.5) . Past 30 years Mitigation (RCP4.5) Business as usual (RCP8.5)
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The results show that under the business as usual scenario the area characterized by TWmax exceeding 31°C is projected to expand to include most of the Southwest Asian coastal regions adjacent to the Gulf, Red Sea and Arabian Sea, with several coastal regions even exceeding the 35 °C threshold.
The study also predicts that by the end of the century, annual TWmax in Abu Dhabi, Dubai, Doha, Dhahran and Bandar Abbas will exceed 35 °C . Further, extreme T max summer events beyond 45 °C will become the ‘norm’ and could pose a threat to the hajj pilgrimage during summer cycles in Saudi Arabia. The authors conclude: ‘ .. regional climate model simulations project that extremes of wet-bulb temperature in the region around the Arabian Gulf are likely to approach and exceed this critical threshold under the business-as-usual scenario of future greenhouse gas concentrations. Our results expose a specific regional hotspot where climate change, in the absence of significant mitigation, is likely to severely impact human habitability in the future.’ |
Alert:
The temperature in Mitribah, Kuwait, reached 54 °C on 21 -7-2016, the hottest temperature recorded outside of Death Valley, California. World Meteorological Organization - WMO - 14-11-2016 :' It is very likely that 2016 will be the hottest year on record, with global ... that they are at a sufficiently high level for 2016 to remain on track for the title of hottest year on record.' |
References:
Jeremy S. Pal, & Elfatih A. B. Eltahir. Future temperature in southwest Asia projected to exceed a threshold for human adaptability . Nature Climate Change, (2015) doi:10.1038/nclimate2833 You may also want to read : J. Lelieveld, Y. Proestos, P. Hadjinicolaou, M. Tanarhte, E. Tyrlis, G. Zittis. Strongly increasing heat extremes in the Middle East and North Africa (MENA) in the 21st century. Climatic Change, 2016; DOI: 10.1007/s10584-016-1665-6 Klaus Klingmüller, Andrea Pozzer, Swen Metzger, Georgiy L. Stenchikov, Jos Lelieveld. Aerosol optical depth trend over the Middle East. Atmospheric Chemistry and Physics, 2016; 16 (8): 5063 DOI: 10.5194/acp-16-5063-2016 Article Rights
CC BY-NC-ND 4.0 Reported on with permission from Macmillan Publishers Ltd: Nature Clim. Change, copyright (2016) nature doi: 10.1038/ nclimate 2833; |