February 15, 2024
Report

A New Paradigm for Observing and Modeling of Air-Sea Interactions to Advance Earth System Prediction

Abstract

The protection of people, property, and environmental resources from extreme weather, seasonal patterns, and climate change drives the need for predictions of weather, ocean, and climate patterns that have skill and value at timescales longer than traditional 1-10-day forecasts, including outlooks spanning weeks to decades. Advancing Earth System Prediction (ESP) skill at this range of timescales requires improved observations, understanding, and modeling of the processes in the ocean boundary layer, the atmospheric boundary layer, and their interface. A new way of referring to this coupled system is the Air-Sea Transition Zone (ASTZ). The report that follows is framed by the paradigm that the ASTZ is a single entity that regulates the flow of energy and matter between the ocean and the atmosphere. The ASTZ is thus the medium through which the ocean and atmosphere respond to and influence one another across their often disparate scales of variability. ASTZ modeling, observing, and understanding needs are particularly acute because very few measurements exist over oceans, and even fewer span the entire ASTZ, even though oceans cover 70% of Earth’s surface and are the source of most of the rain and snow that falls on both the land and the oceans.

Published: February 15, 2024

Citation

Clayson C., C. Demott, S. de Szoeke, P. Chang, G.R. Foltz, R. Krishnamurthy, and T. Lee, et al. 2023. A New Paradigm for Observing and Modeling of Air-Sea Interactions to Advance Earth System Prediction Richland, WA: Pacific Northwest National Laboratory. doi:10.5065/24j7-w583.