Atmospheric aspects of the 2008 Midwest floods: a repeat of 1993?

Coleman, Jill S. M.; Budikova, Dagmar

doi:10.1002/joc.2009

Cited by 29 publications

(26 citation statements)

References 34 publications

(46 reference statements)

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“…Consequently, eastern U.S. summer streamflow responses are more pronounced during the positive phase of the NAO both in terms of the spatial extent as well as magnitude of impact. Yet, a negative spring NAO often precludes warm season flood conditions along the Wabash River Basin in Indiana [ Coleman and Budikova , ]. The composite analysis (Figure c) shows central and southern Indiana summer streamflow is higher after negative NAO springs, but not lower after positive NAO springs.…”

Section: Discussionmentioning

confidence: 99%

“…The Atlantic warm pool may abate the southerly Great Plains low‐level jet (GPLLJ) intensity, yet still increase the magnitude of summer moisture transport northward into the upper Mississippi basin from more moisture‐laden air. The GPLLJ is an important factor on warm season hydrometeorological conditions in the central U.S., particularly notable floods events across the Midwest [ Coleman and Budikova , ; Mo et al ., ; Bell and Janowiak , ]. The strength of the GPLLJ and associated moisture changes are related to the positioning of the Bermuda‐Azores High and the state of the NAO [ Weaver and Nigam , ; Ruiz‐Barradas and Nigam , ].…”

Section: Introductionmentioning

confidence: 99%

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Eastern U.S. summer streamflow during extreme phases of the North Atlantic oscillation

Coleman

Budikova

2013

JGR Atmospheres

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Numerous studies have suggested streamflow discharge in the conterminous U.S. has been increasing, particularly in the east starting in the latter half of the 20th century. Northern Hemisphere (NH) hydroclimatic variability has been connected to shifts in large‐scale atmospheric teleconnection patterns. This study ascertained the spatial and temporal influences of the extreme phases of the North Atlantic Oscillation (NAO) on interannual streamflow variability across the eastern U.S. during the summer season. We also assessed the presence of any delayed streamflow responses to NAO configurations during previous spring (March‐April‐May) and winter (December‐January‐February) seasons across the study area. Methods of inquiry included the use of various statistical and compositing analyses applied to records of mean daily summer streamflow obtained from the Hydro‐Climatic Data Network between 1950 and 2010. Results of this study suggest that summer streamflow across eastern U.S. may be related to and thus potentially predicted from the NAO up to three seasons in advance, information of significant hydrologic consequences for the area. Depending upon the season and geographic location, the relationships may be both linear and nonlinear in nature and may be masked by the presence of temporal trends in the index. Summer streamflow across the eastern U.S., in general, displays greatest response to the negative phase of the NAO during the previous winter and the concurrent summer seasons. Geographically, the greatest potential for predictability exists across the Northeast where cohesive responses to NAO exist in all three seasons, winter, spring, and summer.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Eastern U.S. summer streamflow during extreme phases of the North Atlantic oscillation

Coleman

Budikova

2013

JGR Atmospheres

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“…6, top). Clustering of flood occurrences may be due to persistence of atmospheric processes or to land surface processes associated with soil moisture (see Guetter and Georgakakos 1996;Coleman and Budikova 2010;Villarini et al 2013). 7 (see next section for additional discussion of storm properties).…”

Section: A Hydroclimatologymentioning

confidence: 99%

“…The hydroclimatology of flooding in Iowa is characterized by seasonal maxima of flood occurrences in the April-June time period (Villarini et al 2011a,b;Wang and Chen 2009;Schumacher and Johnson 2006) and by the occurrence of multiple floods during major flood years like 1993 and 2008 Coleman and Budikova 2010;Villarini et al 2013). Links between climate variability and extremes of the hydrologic cycle in Iowa have been examined in previous studies (Changnon and Kunkel 1995;Guetter and Georgakakos 1996;Kunkel et al 1994;Budikova et al 2010;Villarini et al 2013 systems (MCSs).…”

Section: Introductionmentioning

confidence: 99%

Extreme Flood Response: The June 2008 Flooding in Iowa

Smith

Baeck

Villarini

et al. 2013

Journal of Hydrometeorology

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The authors examine the hydroclimatology, hydrometeorology, and hydrology of extreme floods through analyses that center on the June 2008 flooding in Iowa. The most striking feature of the June 2008 flooding was the flood peak of the Cedar River at Cedar Rapids (3964 m 3 s 21 ), which was almost twice the previous maximum from a record of 110 years. The spatial extent of extreme flooding was exceptional, with more U.S. Geological Survey stream gauging stations reporting record flood peaks than in any other year. The 2008 flooding was produced by a sequence of organized thunderstorm systems over a period of two weeks. The authors examine clustering and seasonality of flooding in the Iowa study region and link these properties to features of the June 2008 flood event. They examine the environment of heavy rainfall in Iowa during June 2008 through analyses of composite rainfall fields (15-min time interval and 1-km spatial resolution) developed with the Hydro-NEXRAD system and simulations using the Weather Research and Forecasting Model (WRF). Water balance analyses of extreme flood response, based on rainfall and discharge observations from basins with extreme flooding, suggest that antecedent soil moisture plays a diminishing role in flood response as the return interval increases. Rainfall structure and evolution play a critical and poorly understood role in determining the scaling of flood response. As in other extreme flood studies, analyses of the Iowa flood data suggest that measurement errors can be significant for record discharge estimates.

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“…GPLLJs also influence the intensity and longevity of mesoscale convective complexes 3 , and diurnal variations of the GPLLJ help explain the summertime nocturnal precipitation maximum of the central plains 4 . An anomalously strong GPLLJ contributed to the central U.S. floods of 1993 5 , 2008 6 , and 2015 7 , and increased (decreased) precipitation in the northern (southern) plains observed during 1979–2012 was attributed to a northward expansion of the GPLLJ 8 . Moreover, regional tornado activity is correlated with fluctuations in the GPLLJ’s strength and position 9 .…”

Section: Introductionmentioning

confidence: 97%

Future changes in the climatology of the Great Plains low-level jet derived from fine resolution multi-model simulations

Tang

Winkler

Zhong

et al. 2017

Sci Rep

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The southerly Great Plains low-level jet (GPLLJ) is one of the most significant circulation features of the central U.S. linking large-scale atmospheric circulation with the regional climate. GPLLJs transport heat and moisture, contribute to thunderstorm and severe weather formation, provide a corridor for the springtime migration of birds and insects, enhance wind energy availability, and disperse air pollution. We assess future changes in GPLLJ frequency using an eight member ensemble of dynamically-downscaled climate simulations for the mid-21st century. Nocturnal GPLLJ frequency is projected to increase in the southern plains in spring and in the central plains in summer, whereas current climatological patterns persist into the future for daytime and cool season GPLLJs. The relationship between future GPLLJ frequency and the extent and strength of anticyclonic airflow over eastern North America varies with season. Most simulations project a westward shift of anticyclonic airflow in summer, but uncertainty is larger for spring with only half of the simulations suggesting a westward expansion. The choice of regional climate model and the driving lateral boundary conditions have a large influence on the projected future changes in GPLLJ frequency and highlight the importance of multi-model ensembles to estimate the uncertainty surrounding the future GPLLJ climatology.

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Atmospheric aspects of the 2008 Midwest floods: a repeat of 1993?

Cited by 29 publications

References 34 publications

Eastern U.S. summer streamflow during extreme phases of the North Atlantic oscillation

Eastern U.S. summer streamflow during extreme phases of the North Atlantic oscillation

Extreme Flood Response: The June 2008 Flooding in Iowa

Future changes in the climatology of the Great Plains low-level jet derived from fine resolution multi-model simulations

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