Current and future precipitation extremes over Mississippi and Yangtze River basins as simulated in CMIP5 models

Zaitao Pan, Yuanjie Zhang, Xiaodong Liu, Zhiqiu Gao

Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (1) : 22-36.

Journal of Earth Science ›› 2016, Vol. 27 ›› Issue (1) : 22-36. DOI: 10.1007/s12583-016-0627-2
Article

Current and future precipitation extremes over Mississippi and Yangtze River basins as simulated in CMIP5 models

Author information +
History +

Abstract

Both central-eastern U.S. and China are prone to increasing flooding from Mississippi River and Yangtze River basins respectively. This paper contrasts historical and projected spatialtemporal distribution of extreme precipitation in these two large river basins using 31 CMIP5 (coupled model intercomparison project phase 5) models’ historical and RCP8.5 (representative concentration pathway) experiments. Results show that (1) over both river basins, the heaviest rainfall events have increased in recent decades while the lightest precipitation reduced in frequency. Over Mississippi River Basin, both the lightest precipitation (<2.5 mm/day) and heaviest (>50 mm/day) would decrease in frequency notably after mid-2020s while intermediate events occur more frequently in future; whereas over the Yangtze River Basin, all categories of precipitation are projected to increase in frequency over the coming decades. (2) Although the consensus of CMIP5 models was able to reproduce well domain-time mean and even time-averaged spatial distribution of precipitation, they failed to simulate precipitation trends both in spatial distribution and time means. In a similar fashion, models captured well statistics of precipitation but they had difficulty in representing temporal variations of different precipitation intensity categories. (3) The well-documented 2nd half of the 20th century surface summer cooling over the two river basins showed different associations with precipitation trends with higher anti-correlation between them over the U.S. region, implying different processes contributing to the cooling mechanisms of the two river basins.

Keywords

climate change / extreme precipitation / flooding / GCM simulation

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Zaitao Pan, Yuanjie Zhang, Xiaodong Liu, Zhiqiu Gao. Current and future precipitation extremes over Mississippi and Yangtze River basins as simulated in CMIP5 models. Journal of Earth Science, 2016, 27(1): 22‒36 https://doi.org/10.1007/s12583-016-0627-2

References

Publishing order | Descend order by publishing year | Descend order by cited within
Alexander L. V., Zhang X., Peterson T. C., . Global Observed Changes in Daily Climate Extremes of Temperature and Precipitation. Journal of Geophysical Research, 2006, 111 D05109
CrossRef Google scholar
Arora V. K., Scinocca J. F., Boer G. J., . Carbon Emission Limits Required to Satisfy Future Representative Concentration Pathways of Greenhouse Gases. Geophysical Research Letters, 2011, 38 L05805
CrossRef Google scholar
Bai A., Zhai P. M., Liu X. D. Climatology and Trends of Wet Spells in China. Theoretical and Applied Climatology, 2007, 88(3): 139-148.
CrossRef Google scholar
Bengtsson L. Schulze E.-D. Uncertainties of Global Climate Prediction. Global Biogeochemical Cycles in the Climate System, 2001 London: Academic Press, 15-29.
CrossRef Google scholar
Chen C. T., Knutson T. On the Verification and Comparison of Extreme Rainfall Indices from Climate Models. Journal of Climate, 2008, 21(7): 1605-1621.
CrossRef Google scholar
Chen H. P. Projected Change in Extreme Rainfall Events in China by the End of the 21st Century Using CMIP5 Models. Chinese Science Bulletin, 2013, 58(12): 1462-1472.
CrossRef Google scholar
Chou C., Neelin J. D., Chen C. A., . Evaluating the “Rich-Get-Richer” Mechanism in Tropical Precipitation Change under Global Warming. Journal of Climate, 2009, 22(8): 1982-2005.
CrossRef Google scholar
Collins M., Tett S. F. B., Cooper C. The Internal Climate Variability of HADCM3, a Version of the Hadley Centre Coupled Model without Flux Adjustments. Climate Dynamics, 2001, 17(1): 61-81.
CrossRef Google scholar
Criss R. E. Criss R. E., Kusky T. M. Increased Flooding of Large and Small Watersheds of the Central USA and for the Consequences for Flood Frequency Predictions. Finding the Balance between Floods, Flood Protection, and River Navigation, 2009 Saint Louis: Center for Environmental Sciences at Saint Louis University, 16-21.
Criss R. E. Statistics of Evolving Populations and Their Relevance to Flood. Journal of Earth Science, 2016, 27(1): 2-8.
CrossRef Google scholar
Dai A. G., Fung I. Y., Genio A. D. D. Surface Observed Global Land Precipitation Variations during 1900–88. Journal of Climate, 1997, 10(11): 2943-2962.
CrossRef Google scholar
Deng H. Q., Luo Y., Yao Y., . Spring and Summer Precipitation Changes from 1880 to 2011 and the Future Projections from CMIP5 Models in the Yangtze River Basin, China. Quaternary International, 2013, 304: 95-106.
CrossRef Google scholar
Ding Y. H., Wang Z. Y., Sun Y. Inter-Decadal Variation of the Summer Precipitation in East China and Its Association with Decreasing Asian Summer Monsoon. Part I: Observed Evidences. International Journal of Climatology, 2008, 28(9): 1139-1161.
Donner L. J., Wyman B. L., Hemler R. S., . The Dynamical Core, Physical Parameterizations, and Basic Simulation Characteristics of the Atmospheric Component AM3 of the GFDL Global Coupled Model CM3. Journal of Climate, 2011, 24(13): 3484-3519.
CrossRef Google scholar
Dunne J. P., John J. G., Adcroft A. J., . GFDL’s ESM2 Global Coupled Climate-Carbon Earth System Models. Part I: Physical Formulation and Baseline Simulation Characteristics. Journal of Climate, 2012, 25(19): 6646-6665.
CrossRef Google scholar
Emori S., Brown J. Dynamic and Thermodynamic Changes in Mean and Extreme Precipitation under Changed Climate. Geophysical Research Letters, 2005, 32 17 L17706
CrossRef Google scholar
Feng L., Zhou T. J., Wu B., . Projection of Future Precipitation Change over China with a High-Resolution Global Atmospheric Model. Advances in Atmospheric Sciences, 2011, 28(2): 464-476.
CrossRef Google scholar
Frich P., Alexander L. V., Della-Marta P., . Observed Coherent Changes in Climatic Extremes during the Second Half of the Twentieth Century. Climate Research, 2002, 19: 193-212.
CrossRef Google scholar
Gent P. R., Danabasoglu G., Donner L. J., . The Community Climate System Model Version 4. Journal of Climate, 2011, 24(19): 4973-4991.
CrossRef Google scholar
Giorgetta M. A., Jungclaus J., Reick C. H., . Climate and Carbon Cycle Changes from 1850 to 2100 in MPI-ESM Simulations for the Coupled Model Intercomparison Project Phase 5. Journal of Advances in Modeling Earth Systems, 2013, 5(3): 572-597.
CrossRef Google scholar
Gong D., Wang S. Severe Summer Rainfall in China Associated with Enhanced Global Warming. Climate Research, 2000, 16: 51-59.
CrossRef Google scholar
Groisman P. Y., Karl T. R., Easterling D. R., . Changes in the Probability of Heavy Precipitation: Important Indicators of Climatic Change. Weather and Climate Extremes, 1999, 81: 243-283.
CrossRef Google scholar
Groisman P. Y., Knight R. W., Easterling D. R., . Trends in Intense Precipitation in the Climate Record. Journal of Climate, 2005, 18(9): 1326-1350.
CrossRef Google scholar
Guo Y., Dong W. J., Ren F. M., . Surface Air Temperature Simulations over China with CMIP5 and CMIP3. Advances in Climate Change Research, 2013, 4(3): 145-152.
CrossRef Google scholar
Gutowski W. J. J.r., Willis S. S., Patton J. C., . Changes in Extreme, Cold-Season Synoptic Precipitation Events under Global Warming. Geophysical Research Letters, 2008, 35 L20710
CrossRef Google scholar
Held I. M., Soden B. J. Robust Responses of the Hydrological Cycle to Global Warming. Journal of Climate, 2006, 19(21): 5686-5699.
CrossRef Google scholar
Hourdin F., Musat I., Bony S., . The LMDZ4 General Circulation Model: Climate Performance and Sensitivity to Parametrized Physics with Emphasis on Tropical Convection. Climate Dynamics, 2006, 27(7): 787-813.
CrossRef Google scholar
IPCC, 2013. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York. 1535
Jha M., Pan Z. T., Takle E. S., . Impacts of Climate Change on Streamflow in the Upper Mississippi River Basin: A Regional Climate Model Perspective. Journal of Geophysical Research, 2004, 109 D9 D09105
CrossRef Google scholar
Ji D., Wang L., Feng J., . Description and Basic Evaluation of BNU-ESM Version 1. Geoscientific Model Development Discussions, 2014, 7(2): 1601-1647.
CrossRef Google scholar
Jiang Z. H., Song J., Li L., . Extreme Climate Events in China: IPCC-AR4 Model Evaluation and Projection. Climatic Change, 2011, 110(1): 385-401.
Jiang T., Su B. D., Hartmann H. Temporal and Spatial Trends of Precipitation and River Flow in the Yangtze River Basin, 1961–2000. Geomorphology, 2007, 85(3): 143-154.
CrossRef Google scholar
Jones G. S., Stott P. A., Christidis N. Attribution of Observed Historical Near-Surface Temperature Variations to Anthropogenic and Natural Causes Using CMIP5 Simulations. Journal of Geophysical Research: Atmospheres, 2013, 118(10): 4001-4024.
Karl T. R., Knight R. W., Plummer N. Trends in High-Frequency Climate Variability in the Twentieth Century. Nature, 1995, 377(6546): 217-220.
CrossRef Google scholar
Karl T. R., Knight R. W. Secular Trends of Precipitation Amount, Frequency, and Intensity in the United States. Bulletin of the American Meteorological Society, 1998, 79(2): 231-241.
CrossRef Google scholar
Kharin V. V., Zwiers F. W., Zhang X. B., . Changes in Temperature and Precipitation Extremes in the IPCC Ensemble of Global Coupled Model Simulations. Journal of Climate, 2007, 20(8): 1419-1444.
CrossRef Google scholar
Kueppers L. M., Snyder M. A., Sloan L. C., . Seasonal Temperature Responses to Land-Use Change in the Western United States. Global and Planetary Change, 2008, 60(3): 250-264.
CrossRef Google scholar
Kumar S., Kinter J., Dirmeyer P. A., . Multidecadal Climate Variability and the “Warming Hole” in North America: Results from CMIP5 Twentieth-and Twenty-First-Century Climate Simulations. Journal of Climate, 2013, 26(11): 3511-3527.
CrossRef Google scholar
Kunkel K. E., Andsager K., Easterling D. R. Long-Term Trends in Extreme Precipitation Events over the Conterminous United States and Canada. Journal of Climate, 1999, 12(8): 2515-2527.
CrossRef Google scholar
Kunkel K. E., Liang X. Z., Zhu J. H., . Can CGCMs Simulate the Twentieth-Century “Warming Hole” in the Central United States. Journal of Climate, 2006, 19(17): 4137-4153.
CrossRef Google scholar
Knutti R., Sedlácek J. Robustness and Uncertainties in the New CMIP5 Climate Model Projections. Nature Climate Change, 2013, 3(4): 369-373.
CrossRef Google scholar
Li Q. X., Dong W. J., Li W., . Assessment of the Uncertainties in Temperature Change in China during the Last Century. Chinese Science Bulletin, 2010, 55(19): 1974-1982.
CrossRef Google scholar
Li Q., Zhang H., Chen J., . A Mainland China Homogenized Historical Temperature Dataset of 1951–2004. Bulletin of the American Meteorological Society, 2009, 90(8): 1062-1065.
CrossRef Google scholar
Liang X. Z., Pan J. P., Zhu J. H., . Regional Climate Model Downscaling of the U.S. Summer Climate and Future Change. Journal of Geophysical Research, 2006, 111 D10 D10108
CrossRef Google scholar
Maloney E. D., Camargo S. J., Chang E., . North American Climate in CMIP5 Experiments: Part III: Assessment of Twenty-First-Century Projections. Journal of Climate, 2014, 27(6): 2230-2270.
CrossRef Google scholar
Markakis K., Valari M., Colette A., . Air Quality in the Mid-21st Century for the City of Paris under Two Climate Scenarios: From the Regional to Local Scale. Atmospheric Chemistry and Physics, 2014, 14(14): 7323-7340.
CrossRef Google scholar
Meehl G. A., Arblaster J. M., Branstator G. Mechanisms Contributing to the Warming Hole and the Consequent U.S. East-West Differential of Heat Extremes. Journal of Climate, 2012, 25(18): 6394-6408.
CrossRef Google scholar
Miller A., Cayan D., Barnett T., . The 1976–77 Climate Shift of the Pacific Ocean. Oceanography, 1994, 7: 21-26.
CrossRef Google scholar
Moss R. H., Edmonds J. A., Hibbard K. A., . The Next Generation of Scenarios for Climate Change Research and Assessment. Nature, 2010, 463(7282): 747-756.
CrossRef Google scholar
New M., Hulme M., Jones P. Representing Twentieth-Century Space-Time Climate Variability. Part II: Development of 1901-96 Monthly Grids of Terrestrial Surface Climate. Journal of Climate, 2000, 13(13): 2217-2238.
CrossRef Google scholar
Nigam S., Zhao Y., Ruiz-Barradas A., . Ghil M., Latif M., Wallace M., . The South-Flood North-Drought Pattern over Eastern China and the Drying of the Gangetic Plain: Observations, Simulations, and Origin. Climate Change: Multidecadal and Beyond. World Scientific Series on Asia-Pacific Weather and Climate, 2013 Singapur: World Scientific Publishing Company, 410.
O’Gorman P. A., Schneider T. The Physical Basis for Increases in Precipitation Extremes in Simulations of 21st-Century Climate Change. Proceedings of the National Academy of Sciences, 2009, 106(35): 14773-14777.
CrossRef Google scholar
O’Gorman P. A., Schneider T. Scaling of Precipitation Extremes over a Wide Range of Climates Simulated with an Idealized GCM. Journal of Climate, 2009, 22(21): 5676-5685.
CrossRef Google scholar
Ou T. H., Chen D. L., Linderholm H. W., . Evaluation of Global Climate Models in Simulating Extreme Precipitation in China. Tellus, 2013, 65 19799
CrossRef Google scholar
Pan Z. T., Arritt R. W., Takle E. S., . Altered Hydrologic Feedback in a Warming Climate Introduces a “Warming Hole”. Geophysical Research Letters, 2004, 31 L17109
CrossRef Google scholar
Pan Z. T., Segal M., Li X. Z., . Pryor S., . Global Climate Change Impact on the Midwestern U.S.—A Summer Cooling Trend. Regional Climate Variability, Predictability, and Change in Midwestern USA, 2009 Bloomington: Indiana University Press
Pan Z. T., Pryor S. Pryor S. Overview: Hydrological regime. Regional Climate Variability, Predictability, and Change in Midwestern USA, 2009 Bloomington: Indiana University Press
Pan Z. T., Liu X. D., Kumar S., . Intermodel Variability and Mechanism Attribution of Central and Southeastern U.S. Anomalous Cooling in the Twentieth Century as Simulated by CMIP5 Models. Journal of Climate, 2013, 26(17): 6215-6237.
CrossRef Google scholar
Portmann R. W., Solomon S., Hegerl G. C. Spatial and Seasonal Patterns in Climate Change, Temperatures, and Precipitation across the United States. Proceedings of the National Academy of Sciences, 2009, 106(18): 7324-7329.
CrossRef Google scholar
Riahi K., Rao S., Krey V., . RCP8.5—A Scenario of Comparatively High Greenhouse Gas Emissions. Climatic Change, 2011, 109(1): 33-57.
CrossRef Google scholar
Robinson W. A., Reudy R., Hansen J. E. General Circulation Model Simulations of Recent Cooling in the East-Central United States. Journal of Geophysical Research, 2002, 107 D24 4748
CrossRef Google scholar
Rotstayn L. D., Collier M. A., Dix M. R., . Improved Simulation of Australian Climate and ENSORelated Rainfall Variability in a Global Climate Model with an Interactive Aerosol Treatment. International Journal of Climatology, 2009, 30: 1067-1088.
Schmidt G. A., Ruedy R., Hansen J. E., . Present-Day Atmospheric Simulations Using GISS Model E: Comparison to in situ, Satellite, and Reanalysis Data. Journal of Climate, 2006, 19(2): 153-192.
CrossRef Google scholar
Su B., Jiang T., Ren G., . Observed Trends of Precipitation Extremes in the Yangtze River Basin during 1960 to 2004. Advances in Climate Change Research, 2006, 2(1): 9-14.
Sun J. Q., Ao J. Changes in Precipitation and Extreme Precipitation in a Warming Environment in China. Chinese Science Bulletin, 2012, 58(12): 1395-1401.
CrossRef Google scholar
Tang G. L., Ding Y. H., Wang S. W., . Comparative Analysis of China Surface Air Temperature Series for the Past 100 Years. Advances in Climate Change Research, 2010, 1(1): 11-19.
CrossRef Google scholar
Taylor K. E. Summarizing Multiple Aspects of Model Performance in a Single Diagram. Journal of Geophysical Research, 2001, 106(D7): 7183-7192.
CrossRef Google scholar
Taylor K. E., Stouffer R. J., Meehl G. A. An Overview of CMIP5 and the Experiment Design. Bulletin of the American Meteorological Society, 2012, 93(4): 485-498.
CrossRef Google scholar
Trenberth K. E. Conceptual Framework for Changes of Extremes of the Hydrological Cycle with Climate Change. Climatic Change, 1999, 42: 327-339.
CrossRef Google scholar
Trenberth K. E. Changes in Precipitation with Climate Change. Climate Research, 2011, 47(1): 123-138.
CrossRef Google scholar
Trenberth K. E., Shea D. J. Relationships between Precipitation and Surface Temperature. Geophysical Research Letters, 2005, 32 14 L14703
CrossRef Google scholar
Vose R. S., Easterling D. R., Gleason B. Maximum and Minimum Temperature Trends for the Globe: An Update through 2004. Geophysical Research Letters, 2005, 32 23 L23822
CrossRef Google scholar
Voldoire A., Sanchez-Gomez E., Salas y Mélia D., . The CNRM-CM5.1 Global Climate Model: Description and Basic Evaluation. Climate Dynamics, 2013, 40(9): 2091-2121.
CrossRef Google scholar
Volodin E. M., Dianskii N. A., Gusev A. V. Simulating Present-Day Climate with the INMCM4.0 Coupled Model of the Atmospheric and Oceanic General Circulations. Izvestiya, Atmospheric and Oceanic Physics, 2010, 46(4): 414-431.
CrossRef Google scholar
Wang X., Piao S., Ciais P., . Spring Temperature Change and Its Implication in the Change of Vegetation Growth in North America from 1982 to 2006. Proceedings of the National Academy of Sciences, 2011, 108(4): 1240-1245.
CrossRef Google scholar
Wang H. L., Schubert S., Suarez M., . Attribution of the Seasonality and Regionality in Climate Trends over the United States during 1950–2000. Journal of Climate, 2009, 22(10): 2571-2590.
CrossRef Google scholar
Wang Y. Q., Zhou L. Observed Trends in Extreme Precipitation Events in China during 1961–2001 and the Associated Changes in Large-Scale Circulation. Geophysical Research Letters, 2005, 32 9 L09707
CrossRef Google scholar
Watanabe M., Suzuki T., O’ishi R., . Improved Climate Simulation by MIROC5: Mean States, Variability, and Climate Sensitivity. Journal of Climate, 2010, 23(23): 6312-6335.
CrossRef Google scholar
Williams C. N., Vose R. S., Easterling D. R., . United States Historical Climatology Network Daily Temperature, Precipitation, and Snow Data, 2004
Wilks D. Statistical Methods in the Atmospheric Sciences, 2006, 2 London: Academic Press, 627.
World Bank, 2005. Natural Disaster Hotspots a Global Risk Analysis [2011-8-5]. http://www.preventionweb.net/files/1100_Hotspots.pdf
Wu F. T., Fu C. B. Change of Precipitation Intensity Spectra at Different Spatial Scales under Warming Conditions. Chinese Science Bulletin, 2013, 58(12): 1385-1394.
CrossRef Google scholar
Wu T. W., Yu R. C., Zhang F., . The Beijing Climate Center Atmospheric General Circulation Model: Description and Its Performance for the Present-Day Climate. Climate Dynamics, 2008, 34(1): 123-147.
CrossRef Google scholar
Wuebbles D., Meehl G., Hayhoe K., . CMIP5 Climate Model Analyses: Climate Extremes in the United States. Bulletin of the American Meteorological Society, 2014, 95(4): 571-583.
CrossRef Google scholar
Yukimoto S., Yoshimura H., Hosaka M., . Meteorological Research Institute-Earth System Model Version 1 (MRI-ESM1)—Model Description, 2011
Zhai P., Sun A., Liu X., . Changes in Climate Extremes in China. Climatic Change, 1999, 42: 203-218.
CrossRef Google scholar
Zhang X., Alexander L., Hegerl G. C., . Indices for Monitoring Changes in Extremes Based on Daily Temperature and Precipitation Data, WIREs. Climatic Change, 2011, 2: 851-870.
Zhang H., Fraedrich K., Blender R., . Precipitation Extremes in CMIP5 Simulations on Different Time Scales. Journal of Hydrometeorology, 2013, 14(3): 923-928.
CrossRef Google scholar
Zhang Q., Liu C. L., Xu C. Y., . Observed Trends of Annual Maximum Water Level and Streamflow during Past 130 Years in the Yangtze River Basin, China. Journal of Hydrology, 2006, 324(1–4): 255-265.
CrossRef Google scholar
Zhou T. J., Wang Z. Z., Yu R. C., . The Climate System Model FGOALSs Using LASG/IAP Spectral AGCM SAMIL as Its Atmospheric Component. Acta Meteorologica Sinica, 2005, 63(5): 702-715.

Accesses

Citations

Detail
Sections
Recommended

/