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Evaluating Atmospheric Surface Layer Flux Parameterization within the Coastal Regime.

Authors :
Hlywiak, James
Flagg, David D.
Hong, Xiaodong
Doyle, James D.
Benbow, Charlotte
Curcic, Milan
Darby, Basil
Drennan, William M.
Graber, Hans
Haus, Brian
MacMahan, Jamie
Ortiz-Suslow, David
Ruiz-Plancarte, Jesus
Wang, Qing
Williams, Neil
Yamaguchi, Ryan
Source :
Monthly Weather Review. May2023, Vol. 151 Issue 5, p1045-1072. 28p. 1 Color Photograph, 22 Graphs.
Publication Year :
2023

Abstract

Traditional atmospheric surface layer theory assumes homogeneous surface conditions. Regardless, nearly all surface layer parameterization schemes employed within numerical weather prediction models utilize the same techniques within highly heterogeneous coastal regimes as for homogeneous environments. We compare predicted surface weather and fluxes of momentum, heat, and moisture—focusing mainly on momentum—from regional simulations using the Coupled Ocean–Atmosphere Mesoscale Prediction System (COAMPS) atmospheric model to observations collected from offshore buoys, inland flux towers, and radiosonde profiles during the Coastal Land-Air-Sea Interaction (CLASI) project throughout the summer of 2021 around Monterey Bay, California. Results reveal that modeled cross-coastal surface flux gradients are spuriously discontinuous, leading to systematically overestimated fluxes and weak winds inland of the coastline during onshore flow periods. Additionally, contrary to observations, modeled surface exchange coefficients are insensitive to wind direction on both sides of the coast, which degrades predictive skill downstream from the coastline. Over the central bay, prediction degrades when near-surface wind directions deviate from the prevailing flow direction as the parameterized stress–wind relationship fails during these cases. Predictive skill over the bay is therefore linked to variations in wind direction. Offshore of the geographically complex peninsula, systematic biases are less clear; however, bifurcations in drag coefficients based on wind direction were measured here as well. Last, increasing the horizontal grid spacing from 333 m to 3 km does not significantly affect surface layer prediction. This work highlights the need to reevaluate surface layer parameterization methods for modeling within coastal regions. Significance Statement: Understanding surface layer weather is critical for many purposes, such as infrastructure design and weather forecasting. Within the context of numerical modeling and weather prediction, skillful forecasts of surface winds and temperature rely on accurate portrayal of the surface layer. By comparing observations collected during the Coastal Land-Air-Sea Interaction field program to numerical model solutions, we show that prediction of the surface layer fluxes of momentum, heat, and moisture break down near the coastline, which leads to biases in the predicted surface layer weather both inland and over the water. As surface layer parameterization methods across nearly all numerical models are rooted in the same practices, our results call into question the use of traditional methods near the coastline. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
00270644
Volume :
151
Issue :
5
Database :
Academic Search Index
Journal :
Monthly Weather Review
Publication Type :
Academic Journal
Accession number :
163988590
Full Text :
https://doi.org/10.1175/MWR-D-22-0303.1