资源环境科技发展态势分析平台

Sea breezes occur nearly daily in the U.S. Mid-Atlantic summer during high electricity demand periods, and thus have important implications for the burgeoning U.S. offshore wind energy industry. The sea breeze's offshore component is poorly understood and ill defined relative to its onshore counterpart. Here a new Lagrangian method not yet readily used to study the sea breeze, relative dispersion, was validated and applied to a validated Weather Research and Forecasting model in the U.S. Mid-Atlantic. This Lagrangian method is used to characterize the onshore convergent and offshore divergent sea breeze extents and intensities, and test their sensitivities to both atmospheric synoptic flow and oceanic coastal upwelling, another common summer season regional phenomenon. It was found that offshore-directed synoptic flow impacted the sea breeze onshore extent more than offshore extent, and that coastal upwelling did not significantly impact sea breeze onshore or offshore extent for these carefully selected case studies. Upwelling, however, produced an earlier sea breeze onset (5hr), and a shallower, sharper, and more intense offshore/onshore sea breeze during strong offshore synoptic flow, consistent with past studies. The offshore side of the sea breeze cellwith stronger intensity during upwellingcrossed the New Jersey Wind Energy Area at 1900 UTC, regardless of synoptic wind or upwelling conditions. Results overall are consistent with dynamic linear sea breeze theory. Uncertain projected trends in coastal upwelling/sea breezes in a warming world highlight the importance of continued study of coastal air-sea interactions for improved offshore wind energy assessment and prediction.

Plain Language Summary Sea breezes are important for the emerging U.S. offshore wind energy industry, because they occur frequently during peak energy demand periods (summer afternoons) across many of the nation's coastlines designated for offshore wind energy. However, the offshore component of the sea breezewhere offshore wind turbines operateis poorly understood. Here a Lagrangian analysis technique called relative dispersion is newly applied to a numerical weather prediction model in the U.S. Mid-Atlantic. The new technique enables clearer characterization of the offshore sea breeze component. It was found that winds against the sea breeze prevented the sea breeze from penetrating inland, whereas those same winds largely did not affect the offshore extent of the sea breeze. When coastal upwelling occurredresulting in very cold waters at the beach, the sea breeze began 5hr earlier and was stronger. Regardless of the condition tested, the offshore extent of the sea breeze crossed the New Jersey Wind Energy Area at 1900 UTC. The results here are consistent with past studies and sea breeze theory. The new application of the technique should be a useful tool for further characterization and prediction of the sea breeze offshore, which will be critical for offshore wind energy applications.