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Forecasting Atmospheric Rivers during CalWater 2015 (2017)

Cordeira, Jason M. ; Ralph, F. Martin ; Martin, Andrew ; [et al.]

American Meteorological Society

In: Bulletin of the American Meteorological Society. 2017; 98(3): 449-459. Published 2017 Mar 01. doi: 10.1175/bams-d-15-00245.1.

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Publication Date: 2017-03-01

Description: Atmospheric rivers (ARs) are long and narrow corridors of enhanced vertically integrated water vapor (IWV) and IWV transport (IVT) within the warm sector of extra tropical cyclones that can produce heavy precipitation and flooding in regions of complex terrain, especially along the U.S. West Coast. Several field campaigns have investigated ARs under the CalWater program of field studies. The first field phase of CalWater during 2009–11 increased the number of observations of precipitation and aerosols, among other parameters, across California and sampled ARs in the coastal and near-coastal environment, whereas the second field phase of CalWater during 2014–15 observed the structure and intensity of ARs and aerosols in the coastal and offshore environment over the northeast Pacific. This manuscript highlights the forecasts that were prepared for the CalWater field campaign in 2015, and the development and use of an “AR portal” that was used to inform these forecasts. The AR portal contains archived and real-time deterministic and probabilistic gridded forecast tools related to ARs that emphasize water vapor concentrations and water vapor flux distributions over the eastern North Pacific, among other parameters, in a variety of formats derived from the National Centers for Environmental Prediction (NCEP) Global Forecast System and Global Ensemble Forecast System. The tools created for the CalWater 2015 field campaign provided valuable guidance for flight planning and field activity purposes, and they may prove useful in forecasting ARs and better anticipating hydrometeorological extremes along the U.S. West Coast.

Print ISSN: 0003-0007

Electronic ISSN: 1520-0477

Topics: Geography , Physics

Published by American Meteorological Society

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Landfalling Atmospheric Rivers, the Sierra Barrier Jet, and Extreme Daily Precipitation in Northern California’s Upper Sacramento River Watershed (2016)

Ralph, F. Martin ; Cordeira, Jason M. ; Neiman, Paul J. ; [et al.]

American Meteorological Society

In: Journal of Hydrometeorology. 2016; 17(7): 1905-1914. Published 2016 Jun 27. doi: 10.1175/jhm-d-15-0167.1.

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Publication Date: 2016-06-27

Description: The upper Sacramento River watershed is vital to California’s water supply and is susceptible to major floods. Orographic precipitation in this complex terrain involves both atmospheric rivers (ARs) and the Sierra barrier jet (SBJ). The south-southeasterly SBJ induces orographic precipitation along south-facing slopes in the Mt. Shasta–Trinity Alps, whereas landfalling ARs ascend up and over the statically stable SBJ and induce orographic precipitation along west-facing slopes in the northern Sierra Nevada. This paper explores the occurrence of extreme daily precipitation (EDP) in this region in association with landfalling ARs and the SBJ. The 50 wettest days (i.e., days with EDP) for water years (WYs) 2002–11 based on the average of daily precipitation from eight rain gauges known as the Northern Sierra 8-Station Index (NS8I) are compared to dates from an SSM/I satellite-based landfalling AR-detection method and dates with SBJ events identified from nearby wind profiler data. These 50 days with EDP accounted for 20% of all precipitation during the 10-WY period, or 5 days with EDP per year on average account for one-fifth of WY precipitation. In summary, 46 of 50 (92%) days with EDP are associated with landfalling ARs on either the day before or the day of precipitation, whereas 45 of 50 (90%) days with EDP are associated with SBJ conditions on the day of EDP. Forty-one of 50 (82%) days with EDP are associated with both a landfalling AR and an SBJ. The top 10 days with EDP were all associated with both a landfalling AR and an SBJ.

Print ISSN: 1525-755X

Electronic ISSN: 1525-7541

Topics: Geography , Geosciences , Physics

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Multiscale Upstream and In Situ Precursors to the Elevated Mixed Layer and High-Impact Weather over the Midwest United States (2017)

Cordeira, Jason M. ; Metz, Nicholas D. ; Howarth, Macy E. ; [et al.]

American Meteorological Society

In: Weather and Forecasting. 2017; 32(3): 905-923. Published 2017 Apr 12. doi: 10.1175/waf-d-16-0122.1.

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Publication Date: 2017-04-12

Description: Two severe MCSs over the upper Midwest United States resulted in 〉100 mm of rain in a ~24-h period and 〉200 severe weather reports, respectively, during 30 June–2 July 2011. This period also featured 100 (104) daily maximum high (low) temperature records across the same region. These high-impact weather events occurred in the presence of an elevated mixed layer (EML) that influenced the development of the severe MCSs and the numerous record high temperatures. The antecedent large-scale flow evolution was influenced by early season Tropical Cyclone Meari over the western North Pacific. The recurvature and subsequent interaction of Meari with the extratropical large-scale flow occurred in conjunction with Rossby wave train amplification over the North Pacific and dispersion across North America during 22 June–2 July 2011. The Rossby wave train dispersion contributed to trough (ridge) development over western (central) North America and the development of an EML and the two MCSs over the upper Midwest United States. A composite analysis of 99 warm-season days with an EML at Minneapolis, Minnesota, suggests that Rossby wave train amplification and dispersion across the North Pacific may frequently occur in the 7 days leading up to EMLs across the upper Midwest. The composite analysis also demonstrates an increased frequency of severe weather and elevated temperatures relative to climatology on days with an EML. These results suggest that EMLs over the upper Midwest may often be preceded by Rossby wave train amplification over the North Pacific and be followed by a period of severe weather and elevated temperatures.

Print ISSN: 0882-8156

Electronic ISSN: 1520-0434

Topics: Geography , Physics

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A Scale to Characterize the Strength and Impacts of Atmospheric Rivers (2019)

Ralph, F. Martin ; Rutz, Jonathan J. ; Cordeira, Jason M. ; [et al.]

American Meteorological Society

In: Bulletin of the American Meteorological Society. 2019; 100(2): 269-289. Published 2019 Feb 01. doi: 10.1175/bams-d-18-0023.1.

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Publication Date: 2019-02-01

Description: Atmospheric rivers (ARs) play vital roles in the western United States and related regions globally, not only producing heavy precipitation and flooding, but also providing beneficial water supply. This paper introduces a scale for the intensity and impacts of ARs. Its utility may be greatest where ARs are the most impactful storm type and hurricanes, nor’easters, and tornadoes are nearly nonexistent. Two parameters dominate the hydrologic outcomes and impacts of ARs: vertically integrated water vapor transport (IVT) and AR duration [i.e., the duration of at least minimal AR conditions (IVT ≥ 250 kg m–1 s–1)]. The scale uses an observed or predicted time series of IVT at a given geographic location and is based on the maximum IVT and AR duration at that point during an AR event. AR categories 1–5 are defined by thresholds for maximum IVT (3-h average) of 250, 500, 750, 1,000, and 1,250 kg m–1 s–1, and by IVT exceeding 250 kg m–1 s–1 continuously for 24–48 h. If the AR event duration is less than 24 h, it is downgraded by one category. If it is longer than 48 h, it is upgraded one category. The scale recognizes that weak ARs are often mostly beneficial because they can enhance water supply and snowpack, while stronger ARs can become mostly hazardous, for example, if they strike an area with antecedent conditions that enhance vulnerability, such as burn scars or wet conditions. Extended durations can enhance impacts. Short durations can mitigate impacts.

Print ISSN: 0003-0007

Electronic ISSN: 1520-0477

Topics: Geography , Physics

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West Coast Forecast Challenges and Development of Atmospheric River Reconnaissance (2020)

Ralph, F. Martin ; Cannon, Forest ; Tallapragada, Vijay ; [et al.]

American Meteorological Society

In: Bulletin of the American Meteorological Society. 2020; 101(8): E1357-E1377. Published 2020 Aug 01. doi: 10.1175/bams-d-19-0183.1.

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Publication Date: 2020-08-01

Description: Water management and flood control are major challenges in the western United States. They are heavily influenced by atmospheric river (AR) storms that produce both beneficial water supply and hazards; for example, 84% of all flood damages in the West (up to 99% in key areas) are associated with ARs. However, AR landfall forecast position errors can exceed 200 km at even 1-day lead time and yet many watersheds are

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Observations and Predictability of a High-Impact Narrow Cold-Frontal Rainband over Southern California on 2 February 2019 (2020)

Cannon, Forest ; Oakley, Nina S. ; Hecht, Chad W. ; [et al.]

American Meteorological Society

In: Weather and Forecasting. 2020; 35(5): 2083-2097. Published 2020 Sep 14. doi: 10.1175/waf-d-20-0012.1.

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Publication Date: 2020-09-14

Description: Short-duration, high-intensity rainfall in Southern California, often associated with narrow cold-frontal rainbands (NCFR), threaten life and property. While the mechanisms that drive NCFRs are relatively well understood, their regional characteristics, specific contribution to precipitation hazards, and their predictability in the western United States have received little research attention relative to their impact. This manuscript presents observations of NCFR physical processes made during the Atmospheric River Reconnaissance field campaign on 2 February 2019 and investigates the predictability of the observed NCFR across spatiotemporal scales and forecast lead time. Dropsonde data collected along transects of an atmospheric river (AR) and its attendant cyclone during rapid cyclogenesis, and radiosonde observations during landfall 24 h later, are used to demonstrate that a configuration of the Weather Research and Forecasting (WRF) Model skillfully reproduces the physical processes responsible for the development and maintenance of the impactful NCFR. Ensemble simulations provide quantitative uncertainty information on the representation of these features in numerical weather prediction and instill confidence in the utility of WRF as a forecast guidance tool for short- to medium-range prediction of mesoscale precipitation processes in landfalling ARs. This research incorporates novel data and methodologies to improve forecast guidance for NCFRs impacting Southern California. While this study focuses on a single event, the outlined approach to observing and predicting high-impact weather across a range of spatial and temporal scales will support regional water management and hazard mitigation, in general.

Print ISSN: 0882-8156

Electronic ISSN: 1520-0434

Topics: Geography , Physics

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Hydrometeorological Characteristics of Ice Jams on the Pemigewasset River in Central New Hampshire (2020)

Sanders, Matthew C. ; Cordeira, Jason M. ; Metz, Nicholas D.

American Meteorological Society

In: Journal of Hydrometeorology. 2020; 1-52. Published 2020 Oct 15. doi: 10.1175/jhm-d-20-0027.1. [early online release]

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Publication Date: 2020-10-15

Description: Ice jams that occurred on the Pemigewasset River in central New Hampshire resulted in significant localized flooding on 26 February 2017 and 13 January 2018. Analyses of these two case studies shows that both ice jam events occurred in association with enhanced moisture transport characteristic of atmospheric rivers (ARs) that resulted in rain-on-snow, snow-pack ablation, and rapid increases in streamflow across central New Hampshire. However, while the ice jams and ARs that preceded them were similar, the antecedent hydrometeorological characteristics of the region were different. The February 2017 event featured a “long melting period with low precipitation” scenario, with several days of warm (~5°–20°C) maximum surface temperatures that resulted in extensive snowmelt followed by short-duration, weak AR that produced ~10–15 mm of precipitation during a 6-h period prior to the formation of the ice jam. Alternatively, the January 2018 event featured a “short melting period with high precipitation” scenario with snowmelt that occurred primarily during a more intense and long-duration AR that produced in 〉50 mm of rainfall during a 30-h period prior to the formation of the ice jam. Composite analysis of 20 ice jam events during 1981–2019 illustrates that 19 of 20 events were preceded by environments characterized by ARs along the U.S. East Coast and occur in association with a composite corridor of enhanced integrated water vapor 〉25 mm collocated with integrated water vapor transport magnitudes 〉600 kg m−1 s−1. Additional analyses suggest that most ice jams on the Pemigewasset River share many common synoptic-scale antecedent meteorological characteristics that may provide situational awareness for future events.

Print ISSN: 1525-755X

Electronic ISSN: 1525-7541

Topics: Geography , Geosciences , Physics

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Synoptic and Mesoscale Forcing of Southern California Extreme Precipitation (2018)

Cannon, Forest ; Hecht, Chad W. ; Cordeira, Jason M. ; [et al.]

American Geophysical Union

In: Journal of Geophysical Research: Atmospheres. 2018; 123(16): 13714-13730. Published 2018 Dec 27. doi: 10.1029/2018jd029045.

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Publication Date: 2018-12-27

Description: Southern California water resources are heavily dependent on a small number of extreme precipitation events each winter season, which dictate the region's highly variable interannual accumulations. In the Santa Ana River Watershed, on average, three extreme events per year contribute half of annual precipitation, yet there are relatively few studies of the synoptic to mesoscale processes that drive precipitation during these events. This study uses an ingredient-based approach in identifying the contributions of orographic forcing, dynamical forcing, and convective instability to extreme precipitation in the watershed in 107 storms that produced roughly 50% of all precipitation from 1981 to 2017. The influence of dynamical forcing and convective instability on event precipitation distributions is investigated relative to the dominant influence of orographic forcing that is typically found in landfalling atmospheric rivers. Case studies of two high-impact events from the 2017 winter season demonstrate differences in the roles of synoptic ascent and mesoscale convective features in modifying precipitation location, rate, and accumulation over the watershed. The 17 and 18 February 2017 case study included a narrow cold-frontal rainband that produced high-intensity short-duration precipitation over low elevations of the watershed. In the 107 extreme event records, similar modification of the precipitation distribution toward non-orographic rainfall was related to significant changes in the synoptic-scale circulation that favored enhanced dynamics and upstream ascent associated with frontogenesis. Variability in precipitation mechanisms is of primary interest to weather forecasters and water managers as it modifies event impacts and predictability. ©2018. American Geophysical Union. All Rights Reserved.

Print ISSN: 2169-897X

Electronic ISSN: 2169-8996

Topics: Geosciences , Physics

Published by American Geophysical Union

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Characterizing the influence of atmospheric river orientation and intensity on precipitation distributions over North Coastal California (2017)

Hecht, Chad W. ; Cordeira, Jason M.

American Geophysical Union

In: Geophysical Research Letters. 2017; 44(17): 9048-9058. Published 2017 Sep 09. doi: 10.1002/2017gl074179.

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Publication Date: 2017-09-09

Description: Atmospheric rivers (ARs) are long (〉2000 km) and narrow (500–1000 km) corridors of enhanced vertically integrated water vapor and enhanced integrated water vapor transport (IVT) that are responsible for a majority of global poleward moisture transport and can result in extreme orographic precipitation. Observational evidence suggests that ARs within different synoptic-scale flow regimes may contain different water vapor source regions, orientations, and intensities and may result in different precipitation distributions. This study uses k-means clustering to objectively identify different orientations and intensities of ARs that make landfall over the California Russian River watershed. The ARs with different orientations and intensities occur within different synoptic-scale flow patterns in association with variability in IVT direction and quasi-geostrophic forcing for ascent and lead to different precipitation distributions over the Russian River watershed. These differences suggest that both mesoscale upslope moisture flux and synoptic-scale forcing for ascent are important factors in modulating precipitation distributions during landfalling ARs. ©2017. American Geophysical Union. All Rights Reserved.

Print ISSN: 0094-8276

Electronic ISSN: 1944-8007

Topics: Geosciences , Physics

Published by American Geophysical Union

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High-impact hydrologic events and atmospheric rivers in California: An investigation using the NCEI Storm Events Database (2017)

Young, Allison M. ; Skelly, Klint T. ; Cordeira, Jason M.

American Geophysical Union

In: Geophysical Research Letters. 2017; 44(7): 3393-3401. Published 2017 Apr 14. doi: 10.1002/2017gl073077.

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Publication Date: 2017-04-14

Description: Atmospheric rivers (ARs) are long, narrow corridors of enhanced integrated water vapor and integrated vapor transport that can result in high-impact hydrologic events (HIHEs) including floods, flash floods, and debris flows. This study examined the relationship between HIHEs and ARs in California for 10 water years by using the National Centers for Environmental Information Storm Events Database and a catalog of landfalling ARs provided by Rutz et al. (). Results illustrated that HIHEs related to floods and debris flows are commonly associated with ARs during the cold season across Northern California, whereas HIHEs related to flash floods are commonly not associated with ARs during the warm season across Southern California. Composite analyses illustrated that HIHEs associated with landfalling ARs are associated with synoptic-scale flow patterns that support southwesterly water vapor flux that aligns favorably with California coastal topography to maximize upslope flow and orographic precipitation. ©2017. American Geophysical Union. All Rights Reserved.

Print ISSN: 0094-8276

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