Interpretation of Enhanced Integrated Water Vapor Bands Associated with Extratropical Cyclones: Their Formation and Connection to Tropical Moisture

Bao, Jian‐Wen; Michelson, S. A.; Neiman, Paul J.; Ralph, F. Martin; Wilczak, J. M.

doi:10.1175/mwr3123.1

Cited by 268 publications

(342 citation statements)

References 21 publications

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“…The floods of 1986 and 1997 were the largest recorded in the American River (at about 3 times the normal peak flow), and the 1986 flood was largest in the Russian River (at about twice the normal peak flow). Each of these three storms, and probably the 1862 storm, was fed by ARs that drew tropical and subtropical heat and moisture into California (Bao et al 2006;Leung and Qian 2009).…”

Section: Th Century Stormsmentioning

confidence: 99%

Design and quantification of an extreme winter storm scenario for emergency preparedness and planning exercises in California

et al. 2011

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The USGS Multihazards Project is working with numerous agencies to evaluate and plan for hazards and damages that could be caused by extreme winter storms impacting California. Atmospheric and hydrological aspects of a hypothetical storm scenario have been quantified as a basis for estimation of human, infrastructure, economic, and environmental impacts for emergency-preparedness and flood-planning exercises. In order to ensure scientific defensibility and necessary levels of detail in the scenario description, selected historical storm episodes were concatentated to describe a rapid arrival of several major storms over the state, yielding precipitation totals and runoff rates beyond those occurring during the individual historical storms. This concatenation allowed the scenario designers to avoid arbitrary scalings and is based on historical occasions from the 19th and 20th Centuries when storms have stalled over the state and when extreme storms have arrived in rapid succession. Dynamically consistent, hourly precipitation, temperatures, barometric pressures (for consideration of storm surges and coastal erosion), and winds over California were developed for the so-called ARkStorm scenario by downscaling the concatenated global records of the historical storm sequences onto 6-and 2-km grids using a regional weather model of January 1969 and February 1986 storm conditions. The weather model outputs were then used to force a hydrologic model to simulate ARkStorm runoff, to better understand resulting flooding risks. Methods used to build this scenario can be applied to other emergency, nonemergency and non-California applications.

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Section: Th Century Stormsmentioning

confidence: 99%

Design and quantification of an extreme winter storm scenario for emergency preparedness and planning exercises in California

et al. 2011

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“…The Mediterranean appears as a strong contributor, while for instance the Atlantic seems to provide less moisture to central Europe. In the Pacific, Ralph et al (2004) and Bao et al (2006) examined the water transport in midlatitude IWV filaments (also called 'tropospheric rivers' or 'moisture conveyor belts'), but mentioned the difficulty of identifying the associated moisture sources, since the IWV filaments can also form due to horizontal convergence. More recently, Stohl et al (2008) used a Lagrangian moisture diagnostic to identify the moisture sources for an IWV filament related to the extratropical transition of two hurricanes, and found moisture contributions from a large range of latitudes.…”

Section: Evolution Of the Meteorological Situationmentioning

confidence: 99%

Sources of water vapour contributing to the Elbe flood in August 2002—A tagging study in a mesoscale model

Sodemann

Wernli²,

Schwierz

2009

Quart J Royal Meteoro Soc

103

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ABSTRACT:In this study we investigate the contribution of various moisture sources to the Elbe flood that occurred in Central Europe during August 2002. An 8-day simulation with the mesoscale numerical weather prediction model CHRM, including newly implemented water vapour tracers, has been performed. According to the simulation, rather than drawing moisture from one single dominant source region, water vapour from widely separated moisture sources contributed to the extreme precipitation in the most affected area, notably at distinct, subsequent periods of time, and each in significant amounts. These moisture sources include the Atlantic and Mediterranean ocean areas inside the model domain, evapotranspiration from land areas, and long-range advection from subtropical areas outside the model domain.The results highlight the importance of the concurrent upper-level circulation and the mesoscale flow structures associated with the cyclone for producing extreme precipitation in parts of Germany, Austria, and the Czech Republic during that period. Furthermore, the numerical and technical problems of implementing water vapour tracers into a limited-area model are discussed, including conservative tracer advection, initialization, boundary treatment, and the handling of precipitation parametrizations. An evaluation of the consistency of the method in terms of water vapour, cloud water, and precipitation is provided, with generally satisfying results. The model with its detailed water vapour tracer implementation can now be used for further case-studies and climatological simulations, and serve as a reference for evaluating the performance of other moisture tracking methods, such as those based on backward trajectories.

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“…Atmospheric rivers (ARs) are one of the primary large-scale dynamical features that bring large amounts of water vapor from tropics to the US west coast, and they can create extreme rainfall and floods (Bao et al, 2006;Ralph et al, 2011;Neiman et al, 2010). Aerosols can modify cloud microphysical processes and potentially alter the location, intensity, and type of precipitation (Tao et al, 2012) by acting as cloud condensation nuclei (CCN) or ice nucleating particles (INPs).…”

Section: Introductionmentioning

confidence: 99%

Effects of cloud condensation nuclei and ice nucleating particles on precipitation processes and supercooled liquid in mixed-phase orographic clouds

et al. 2017

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Abstract. How orographic mixed-phase clouds respond to the change in cloud condensation nuclei (CCN) and ice nucleating particles (INPs) are highly uncertain. The main snow production mechanism in warm and cold mixed-phase orographic clouds (referred to as WMOCs and CMOCs, respectively, distinguished here as those having cloud tops warmer and colder than −20 • C) could be very different. We quantify the CCN and INP impacts on supercooled water content, cloud phases, and precipitation for a WMOC case and a CMOC case, with sensitivity tests using the same CCN and INP concentrations between the WMOC and CMOC cases. It was found that deposition plays a more important role than riming for forming snow in the CMOC case, while the role of riming is dominant in the WMOC case. As expected, adding CCN suppresses precipitation, especially in WMOCs and low INPs. However, this reverses strongly for CCN of 1000 cm −3 and larger. We found a new mechanism through which CCN can invigorate mixed-phase clouds over the Sierra Nevada and drastically intensify snow precipitation when CCN concentrations are high (1000 cm −3 or higher). In this situation, more widespread shallow clouds with a greater amount of cloud water form in the Central Valley and foothills west of the mountain range. The increased latent heat release associated with the formation of these clouds strengthens the local transport of moisture to the windward slope, invigorating mixed-phase clouds over the mountains, and thereby producing higher amounts of snow precipitation. Under all CCN conditions, increasing the INPs leads to decreased riming and mixed-phase fraction in the CMOC as a result of liquid-limited conditions, but has the opposite effects in the WMOC as a result of ice-limited conditions. However, precipitation in both cases is increased by increasing INPs due to an increase in deposition for the CMOC but enhanced riming and deposition in the WMOC. Increasing the INPs dramatically reduces supercooled water content and increases the cloud glaciation temperature, while increasing CCN has the opposite effect with much smaller significance.

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Interpretation of Enhanced Integrated Water Vapor Bands Associated with Extratropical Cyclones: Their Formation and Connection to Tropical Moisture

Cited by 268 publications

References 21 publications

Design and quantification of an extreme winter storm scenario for emergency preparedness and planning exercises in California

Design and quantification of an extreme winter storm scenario for emergency preparedness and planning exercises in California

Sources of water vapour contributing to the Elbe flood in August 2002—A tagging study in a mesoscale model

Effects of cloud condensation nuclei and ice nucleating particles on precipitation processes and supercooled liquid in mixed-phase orographic clouds

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