Identification of extreme precipitation threat across midlatitude regions based on short-wave circulations

Identification of extreme precipitation threat across midlatitude regions based on short-wave circulations

The most severe thunderstorms, producing extreme precipitation, occur over subtropical and midlatitude regions. Atmospheric conditions conducive to organized, intense thunderstorms commonly involve the coupling of a low‐level jet (LLJ) with a synoptic short wave. The midlatitude synoptic activity is...

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Veröffentlicht in:Journal of geophysical research. Atmospheres 2013-10, Vol.118 (19), p.11,059-11,074
Hauptverfasser: Wang, Shih-Yu, Davies, Robert E., Gillies, Robert R.
Format: Artikel
Sprache:eng
Schlagworte:
Air pollution
Circulation
climate change
Drought
Earth, ocean, space
Exact sciences and technology
External geophysics
Extreme
Extreme weather
flood
Floods
Geophysics
Greenhouse gases
Hydrologic data
Joining
Meteorology
Precipitation
Short wave
short waves
Thunderstorms
Trends
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container_end_page 11,074
container_issue 19
container_start_page 11,059
container_title Journal of geophysical research. Atmospheres
container_volume 118
creator Wang, Shih-Yu
Davies, Robert E.
Gillies, Robert R.
description The most severe thunderstorms, producing extreme precipitation, occur over subtropical and midlatitude regions. Atmospheric conditions conducive to organized, intense thunderstorms commonly involve the coupling of a low‐level jet (LLJ) with a synoptic short wave. The midlatitude synoptic activity is frequently modulated by the circumglobal teleconnection (CGT), in which meridional gradients of the jet stream act as a guide for short Rossby waves. Previous research has linked extreme precipitation events with either the CGT or the LLJ but has not linked the two circulation features together. In this study, a circulation‐based index was developed by combining (a) the degree of the CGT and LLJ coupling, (b) the extent to which this CGT‐LLJ coupling connects to regional precipitation and (c) the spatial correspondence with the CGT (short wave) trending pattern over the recent 32 years (1979–2010). Four modern‐era global reanalyses, in conjunction with four gridded precipitation data sets, were utilized to minimize spurious trends. The results are suggestive of a link between the CGT/LLJ trends and several recent extreme precipitation events, including those leading to the 2008 Midwest flood in U.S., the 2011 tornado outbreaks in southeastern U.S., the 2010 Queensland flood in northeastern Australia, and to the opposite side the 2012 central U.S. drought. Moreover, an analysis of three Coupled Model Intercomparison Project Phase 5 models from the historical experiments points to the role of greenhouse gases in forming the CGT trends during the warm season. Key Points The arctic amplification likely modifies short‐wave circulations Modified upper‐level circulation affects low‐level moisture flux The combined effect enhances precipitation extremes in certain regions
doi_str_mv 10.1002/jgrd.50841
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Atmospheric conditions conducive to organized, intense thunderstorms commonly involve the coupling of a low‐level jet (LLJ) with a synoptic short wave. The midlatitude synoptic activity is frequently modulated by the circumglobal teleconnection (CGT), in which meridional gradients of the jet stream act as a guide for short Rossby waves. Previous research has linked extreme precipitation events with either the CGT or the LLJ but has not linked the two circulation features together. In this study, a circulation‐based index was developed by combining (a) the degree of the CGT and LLJ coupling, (b) the extent to which this CGT‐LLJ coupling connects to regional precipitation and (c) the spatial correspondence with the CGT (short wave) trending pattern over the recent 32 years (1979–2010). Four modern‐era global reanalyses, in conjunction with four gridded precipitation data sets, were utilized to minimize spurious trends. The results are suggestive of a link between the CGT/LLJ trends and several recent extreme precipitation events, including those leading to the 2008 Midwest flood in U.S., the 2011 tornado outbreaks in southeastern U.S., the 2010 Queensland flood in northeastern Australia, and to the opposite side the 2012 central U.S. drought. Moreover, an analysis of three Coupled Model Intercomparison Project Phase 5 models from the historical experiments points to the role of greenhouse gases in forming the CGT trends during the warm season. 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Four modern‐era global reanalyses, in conjunction with four gridded precipitation data sets, were utilized to minimize spurious trends. The results are suggestive of a link between the CGT/LLJ trends and several recent extreme precipitation events, including those leading to the 2008 Midwest flood in U.S., the 2011 tornado outbreaks in southeastern U.S., the 2010 Queensland flood in northeastern Australia, and to the opposite side the 2012 central U.S. drought. Moreover, an analysis of three Coupled Model Intercomparison Project Phase 5 models from the historical experiments points to the role of greenhouse gases in forming the CGT trends during the warm season. 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subjects Air pollution
Circulation
climate change
Drought
Earth, ocean, space
Exact sciences and technology
External geophysics
Extreme
Extreme weather
flood
Floods
Geophysics
Greenhouse gases
Hydrologic data
Joining
Meteorology
Precipitation
Short wave
short waves
Thunderstorms
Trends
title Identification of extreme precipitation threat across midlatitude regions based on short-wave circulations
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