Intensification of Global Hydrological Droughts Under Anthropogenic Climate Warming

Anthropogenic climate warming is expected to accelerate the hydrological cycle with significant consequences for hydrological droughts. However, a systematic understanding of climate warming impacts on the global hydrological droughts and their driving mechanisms is still lacking. Here, we integrate bias‐corrected climate experiments, multiple hydrological models (HYs), and a multivariate analysis of variance (ANOVA) with a machine learning modeling framework, to examine the evolving frequency and multivariate characteristics of hydrological droughts and their mechanisms under climate warming for 6,688 catchments in the five principal Köppen‐Geiger climate zones. Results show that the total frequency of hydrological droughts is likely to stay unchanged while extreme hydrological droughts (e.g., events with a 30 yr joint return period, JRP) are projected to occur more frequently across the 21st century. The historical 30 yr JRP events assessed during the historical baseline period of 1985–2014 could become twice as frequent over ∼60% of global catchments by 2071–2100 under the middle and high emission scenarios (ESs). Climate uncertainty (i.e., from global climate models and ESs) is the major source of uncertainty over temperate and tropical catchments, versus HY uncertainty in arid catchments with locally complex runoff regimes. Our machine learning framework indicates that precipitation stress controls the development of historical droughts over ∼87% of global catchments. However, with climate warming, air temperature variations are expected to become the new primary driver of droughts in high‐latitude cold catchments. This study highlights an increasing risk of global extreme hydrological droughts with warming and suggests that rising temperatures in high latitudes may lead to more extreme hydrological droughts.

[1]  P. Gentine,et al.  Global Increases in Lethal Compound Heat Stress: Hydrological Drought Hazards Under Climate Change , 2022, Geophysical Research Letters.

[2]  Jui-Pin Wang,et al.  Projection of droughts and their socioeconomic exposures based on terrestrial water storage anomaly over China , 2022, Science China Earth Sciences.

[3]  J. Fasullo,et al.  Twenty-first century hydroclimate: A continually changing baseline, with more frequent extremes , 2022, Proceedings of the National Academy of Sciences of the United States of America.

[4]  Jun Xia,et al.  Impacts of Global Climate Warming on Meteorological and Hydrological Droughts and Their Propagations , 2022, Earth's Future.

[5]  S. Mukherjee,et al.  A Multivariate Flash Drought Indicator for Identifying Global Hotspots and Associated Climate Controls , 2022, Geophysical Research Letters.

[6]  T. Gan,et al.  Twenty-first century drought analysis across China under climate change , 2021, Climate Dynamics.

[7]  Robb M. Randall,et al.  Global distribution, trends, and drivers of flash drought occurrence , 2021, Nature Communications.

[8]  T. Keenan,et al.  Exacerbated drought impacts on global ecosystems due to structural overshoot , 2021, Nature Ecology & Evolution.

[9]  B. Lyon,et al.  Spatial Extents of Tropical Droughts During El Niño in Current and Future Climate in Observations, Reanalysis, and CMIP5 Models , 2021, Geophysical Research Letters.

[10]  P. Döll,et al.  Analyzing the Impact of Streamflow Drought on Hydroelectricity Production: A Global‐Scale Study , 2021, Water Resources Research.

[11]  A. Russo,et al.  Recent increasing frequency of compound summer drought and heatwaves in Southeast Brazil , 2021 .

[12]  O. Rakovec,et al.  Increased future occurrences of the exceptional 2018–2019 Central European drought under global warming , 2020, Scientific Reports.

[13]  Chong-yu Xu,et al.  A Framework to Quantify the Uncertainty Contribution of GCMs Over Multiple Sources in Hydrological Impacts of Climate Change , 2020, Earth's Future.

[14]  Yawar Hussain,et al.  Reliability of SM2RAIN precipitation datasets in comparison to gauge observations and hydrological modelling over arid regions , 2020, International Journal of Climatology.

[15]  S. Ohrel,et al.  Global hunger and climate change adaptation through international trade , 2020, Nature Climate Change.

[16]  S. Seneviratne,et al.  Observed changes in dry-season water availability attributed to human-induced climate change , 2020, Nature Geoscience.

[17]  L. Tallaksen,et al.  The 2018 northern European hydrological drought and its drivers in a historical perspective , 2020, Hydrology and Earth System Sciences.

[18]  J. Thepaut,et al.  The ERA5 global reanalysis , 2020, Quarterly Journal of the Royal Meteorological Society.

[19]  A. P. Williams,et al.  Twenty‐First Century Drought Projections in the CMIP6 Forcing Scenarios , 2020, Earth's Future.

[20]  M. L. Kurnaz,et al.  Future Global Meteorological Drought Hot Spots: A Study Based on CORDEX Data , 2020, Journal of Climate.

[21]  F. Brissette,et al.  Frequency change of future extreme summer meteorological and hydrological droughts over North America , 2020 .

[22]  A. Pitman,et al.  Robust Future Changes in Meteorological Drought in CMIP6 Projections Despite Uncertainty in Precipitation , 2020, Geophysical Research Letters.

[23]  Anoop Valiya Veettil,et al.  Multiscale hydrological drought analysis: Role of climate, catchment and morphological variables and associated thresholds , 2020 .

[24]  A. Mishra,et al.  Quantifying Climate and Catchment Control on Hydrological Drought in the Continental United States , 2020, Water Resources Research.

[25]  F. Brissette,et al.  Evaluation of the ERA5 reanalysis as a potential reference dataset for hydrological modeling over North-America , 2019 .

[26]  A. Holtslag,et al.  Low-level jets over the North Sea based on ERA5 and observations: together they do better , 2019, Wind Energy Science.

[27]  Yuanbo Liu,et al.  An Approach to Tracking Meteorological Drought Migration , 2019, Water Resources Research.

[28]  Stefan Lange,et al.  Trend-preserving bias adjustment and statistical downscaling with ISIMIP3BASD (v1.0) , 2019, Geoscientific Model Development.

[29]  Chong-yu Xu,et al.  A framework for quantifying the impacts of climate change and human activities on hydrological drought in a semiarid basin of Northern China , 2019, Hydrological Processes.

[30]  Xing Yuan,et al.  More severe hydrological drought events emerge at different warming levels over the Wudinghe watershed in northern China , 2019, Hydrology and Earth System Sciences.

[31]  Claude N. Williams,et al.  The Global Historical Climatology Network Monthly Temperature Dataset, Version 4 , 2018, Journal of Climate.

[32]  A. Berg,et al.  Present and future Köppen-Geiger climate classification maps at 1-km resolution , 2018, Scientific Data.

[33]  Shenglian Guo,et al.  Large increase in global storm runoff extremes driven by climate and anthropogenic changes , 2018, Nature Communications.

[34]  T. Oki,et al.  The Effect of Global Warming on Future Water Availability: CMIP5 Synthesis , 2018, Water Resources Research.

[35]  R. Betts,et al.  Global Changes in Drought Conditions Under Different Levels of Warming , 2018 .

[36]  Eric F. Wood,et al.  MSWEP V2 Global 3-Hourly 0.1° Precipitation: Methodology and Quantitative Assessment , 2018, Bulletin of the American Meteorological Society.

[37]  J. Smerdon,et al.  Projected drought risk in 1.5°C and 2°C warmer climates , 2017 .

[38]  T. McVicar,et al.  Lags in hydrologic recovery following an extreme drought: Assessing the roles of climate and catchment characteristics , 2017 .

[39]  François Brissette,et al.  Improving Hydrological Model Simulations with Combined Multi-Input and Multimodel Averaging Frameworks , 2017 .

[40]  F. Ludwig,et al.  Projections of future floods and hydrological droughts in Europe under a +2°C global warming , 2016, Climatic Change.

[41]  Qiuhong Tang,et al.  Climate change impacts on meteorological, agricultural and hydrological droughts in China , 2015 .

[42]  Rolf Weingartner,et al.  Robust changes and sources of uncertainty in the projected hydrological regimes of Swiss catchments , 2014 .

[43]  D. Frierson,et al.  Scaling Potential Evapotranspiration with Greenhouse Warming , 2014 .

[44]  S. Hagemann,et al.  Hydrological droughts in the 21st century, hotspots and uncertainties from a global multimodel ensemble experiment , 2013, Proceedings of the National Academy of Sciences.

[45]  Andrea Castelletti,et al.  Assessing the predictive capability of randomized tree-based ensembles in streamflow modelling , 2013 .

[46]  B. Narsimlu,et al.  Assessment of Future Climate Change Impacts on Water Resources of Upper Sind River Basin, India Using SWAT Model , 2013, Water Resources Management.

[47]  A. Castelletti,et al.  Tree‐based iterative input variable selection for hydrological modeling , 2013 .

[48]  Bin Wang,et al.  Divergent global precipitation changes induced by natural versus anthropogenic forcing , 2013, Nature.

[49]  P. Whitfield,et al.  Reference hydrologic networks II. Using reference hydrologic networks to assess climate-driven changes in streamflow , 2012 .

[50]  Cha Zhang,et al.  Ensemble Machine Learning: Methods and Applications , 2012 .

[51]  H.A.J. van Lanen,et al.  A process-based typology of hydrological drought , 2011 .

[52]  Fabrizio Durante,et al.  On the return period and design in a multivariate framework , 2011 .

[53]  D. Hannah,et al.  Regional hydrological drought in north‐western Europe: linking a new Regional Drought Area Index with weather types , 2011 .

[54]  O. Phillips,et al.  The 2010 Amazon Drought , 2011, Science.

[55]  S. Seneviratne,et al.  Recent decline in the global land evapotranspiration trend due to limited moisture supply , 2010, Nature.

[56]  Udaya B. Kogalur,et al.  High-Dimensional Variable Selection for Survival Data , 2010 .

[57]  Hoshin Vijai Gupta,et al.  Decomposition of the mean squared error and NSE performance criteria: Implications for improving hydrological modelling , 2009 .

[58]  S. Shukla,et al.  Use of a standardized runoff index for characterizing hydrologic drought , 2008 .

[59]  G. Vecchi,et al.  Expansion of the Hadley cell under global warming , 2007 .

[60]  C. Perrin,et al.  Improvement of a parsimonious model for streamflow simulation , 2003 .

[61]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[62]  Zhao Ren-jun,et al.  The Xinanjiang model applied in China , 1992 .

[63]  S. Sorooshian,et al.  Effective and efficient global optimization for conceptual rainfall‐runoff models , 1992 .

[64]  J. Hosking L‐Moments: Analysis and Estimation of Distributions Using Linear Combinations of Order Statistics , 1990 .

[65]  H. Akaike A new look at the statistical model identification , 1974 .

[66]  S. Bergström,et al.  DEVELOPMENT OF A CONCEPTUAL DETERMINISTIC RAINFALL-RUNOFF MODEL , 1973 .

[67]  Shenglian Guo,et al.  Projected increases in magnitude and socioeconomic exposure of global droughts in 1.5 °C and 2 °C warmer climates , 2019 .

[68]  V. Singh,et al.  Application and testing of the simple rainfall-runoff model SIMHYD , 2002 .

[69]  B. Kowalski,et al.  Partial least-squares regression: a tutorial , 1986 .