Storm surge along the Pacific coast of North America

TitleStorm surge along the Pacific coast of North America
Publication TypeJournal Article
Year of Publication2017
AuthorsBromirski PD, Flick RE, Miller AJ
JournalJournal of Geophysical Research-Oceans
Volume122
Pagination441-457
Date Published2017/01
Type of ArticleArticle
ISBN Number2169-9275
Accession NumberWOS:000394996400026
Keywordscalifornia coast; climate change; effect; El Nino; el-nino; Hadley circulation; hemisphere winter; impacts; ocean wave impacts; oscillation; projections; sea level pressure inverse barometer; sea-level; storm surge; variability; wave climate
Abstract

Storm surge is an important factor that contributes to coastal flooding and erosion. Storm surge magnitude along eastern North Pacific coasts results primarily from low sea level pressure (SLP). Thus, coastal regions where high surge occurs identify the dominant locations where intense storms make landfall, controlled by storm track across the North Pacific. Here storm surge variability along the Pacific coast of North America is characterized by positive nontide residuals at a network of tide gauge stations from southern California to Alaska. The magnitudes of mean and extreme storm surge generally increase from south to north, with typically high amplitude surge north of Cape Mendocino and lower surge to the south. Correlation of mode 1 nontide principal component (PC1) during winter months (December-February) with anomalous SLP over the northeast Pacific indicates that the dominant storm landfall region is along the Cascadia/British Columbia coast. Although empirical orthogonal function spatial patterns show substantial interannual variability, similar correlation patterns of nontide PC1 over the 1948-1975 and 1983-2014 epochs with anomalous SLP suggest that, when considering decadal-scale time periods, storm surge and associated tracks have generally not changed appreciably since 1948. Nontide PC1 is well correlated with PC1 of both anomalous SLP and modeled wave height near the tide gauge stations, reflecting the interrelationship between storms, surge, and waves. Weaker surge south of Cape Mendocino during the 2015-2016 El Nino compared with 1982-1983 may result from changes in Hadley circulation. Importantly from a coastal impacts perspective, extreme storm surge events are often accompanied by high waves.

DOI10.1002/2016jc012178
Short TitleJ Geophys Res-Oceans
Student Publication: 
No