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Atmospheric river families: Definition and associated synoptic conditions

TitleAtmospheric river families: Definition and associated synoptic conditions
Publication TypeJournal Article
Year of Publication2019
AuthorsFish M.A, Wilson A.M, Ralph FM
Date Published2019/10
Type of ArticleArticle
ISBN Number1525-755X
Accession NumberWOS:000494433200001
KeywordsAtmospheric circulation; california; dropsonde observations; extratropical cyclones; Extreme events; impacts; Meteorology & Atmospheric Sciences; pacific-ocean; precipitation; scale; Synoptic-scale processes; us west-coast; water-vapor transport; weather; winter storm

Atmospheric rivers (ARs) can cause flooding when they are strong and stall over an already wet watershed. While earlier studies emphasized the role of individual, long-duration ARs in triggering floods, it is not uncommon for floods to be associated with a series of ARs that strike in close succession. This study uses measurements from an atmospheric river observatory at Bodega Bay (BBY), in Northern California, to identify periods when multiple AR events occurred in rapid succession. Here, an AR "event" is the period when AR conditions are present continuously at BBY. An objective method is developed to identify such periods, and the concept of "AR families" is introduced. During the period studied there were 228 AR events. Using the AR family identification method, a range of aggregation periods (the length of time allowed for ARs to be considered part of a family) was tested. For example, for an aggregation period of 5 days, there were 109 AR families, with an average of 2.7 ARs per family. Over a range of possible aggregation periods, typically there were 2-6 ARs per family. Compared to single AR events, the synoptic environment of AR families is characterized by lower geopotential heights throughout the midlatitude North Pacific, an enhanced subtropical high, and a stronger zonal North Pacific jet. Analysis of water year 2017 demonstrated a persistent geopotential height dipole throughout the North Pacific and a positive anomaly of integrated water vapor extending toward California. AR families were favored when synoptic features were semistationary.

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