The 2018 Kerala floods: a climate change perspective

In August 2018, the Indian state of Kerala received an extended period of very heavy rainfall as a result of a low-pressure system near the beginning of the month being followed several days later by a monsoon depression. The resulting floods killed over 400 people and displaced a million more. Here...

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Veröffentlicht in:	Climate dynamics 2020-02, Vol.54 (3-4), p.2433-2446
Hauptverfasser:	Hunt, Kieran M. R., Menon, Arathy
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Schlagworte:	Boundary conditions Climate change Climate models Climatology Computer simulation Earth and Environmental Science Earth Sciences Flood control Flooding Floods Future climates Geophysics/Geodesy Global temperature changes Heavy rainfall Hydrologic models Hydrology India Low pressure Meteorological research Monsoon depressions Monsoons Numerical weather forecasting Oceanography Pressure Rain Rain and rainfall Rainfall Resolution Rivers Stream discharge Stream flow Streamflow Tropical climate Troposphere Weather forecasting
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description	In August 2018, the Indian state of Kerala received an extended period of very heavy rainfall as a result of a low-pressure system near the beginning of the month being followed several days later by a monsoon depression. The resulting floods killed over 400 people and displaced a million more. Here, a high resolution setup (4 km) of the Weather Research and Forecasting (WRF) model is used in conjunction with a hydrological model (WRF-Hydro, run at 125 m resolution) to explore the circumstances that caused the floods. In addition to a control experiment, two additional experiments are performed by perturbing the boundary conditions to simulate the event in pre-industrial and RCP8.5 background climates. Modelled rainfall closely matched observations over the study period, and it is found that this would this would have been about 18% heavier in the pre-industrial due to recent weakening of monsoon low-pressure systems, but would be 36% heavier in an RCP8.5 climate due to moistening of the tropical troposphere. Modelled river streamflow responds accordingly: it is shown the six major reservoirs that serve the state would have needed to have 34% more capacity to handle the heavy rainfall, and 43% had the deluge been amplified by an RCP8.5 climate. It is further shown that this future climate would have significantly extended the southern boundary of the flooding. Thus it is concluded that while climate change to date may well have mitigated the impacts of the flooding, future climate change would likely exacerbate them.
doi_str_mv	10.1007/s00382-020-05123-7
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subjects	Boundary conditions Climate change Climate models Climatology Computer simulation Earth and Environmental Science Earth Sciences Flood control Flooding Floods Future climates Geophysics/Geodesy Global temperature changes Heavy rainfall Hydrologic models Hydrology India Low pressure Meteorological research Monsoon depressions Monsoons Numerical weather forecasting Oceanography Pressure Rain Rain and rainfall Rainfall Resolution Rivers Stream discharge Stream flow Streamflow Tropical climate Troposphere Weather forecasting
title	The 2018 Kerala floods: a climate change perspective
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