@article{8f5162b2fd194ea393ce6daa4cf763cd,
title = "Toward a process-oriented understanding of water in the climate system: recent insights from stable isotopes",
abstract = "Describing the processes that regulate the flows and exchanges of water within the atmosphere and between the atmosphere and Earth{\textquoteright}s surface is critical for understanding environmental change and predicting Earth{\textquoteright}s future accurately. The heavy-to-light hydrogen and oxygen isotope ratios of water provide a useful lens through which to evaluate these processes due to their innate sensitivity to evaporation, condensation, and mixing. In this review, we examine how isotopic information advances our understanding about the origin and transport history of moisture in the atmosphere and about convective processes—including cloud mixing and detrainment, precipitation formation, and rain evaporation. Moreover, we discuss how isotopic data can be used to benchmark numerical simulations across a range of scales and improve predictive skill through data assimilation techniques. This synthesis of work illustrates that, when paired with air mass thermodynamic properties that are commonly measured and modeled (such as specific humidity and temperature), water{\textquoteright}s isotope ratios help shed light on moist processes that help set the climate state.",
keywords = "climate, clouds and precipitation, convection, moisture transport, water cycle, water isotopes",
author = "Adriana Bailey and David Noone and Sylvia Dee and Jesse Nusbaumer and Jessica Conroy and Samantha Stevenson and Alyssa Atwood",
note = "This review paper was motivated by discussions of the US CLIVAR Working Group on Water Isotopes, which was jointly supported by NASA, NOAA, NSF programs in Paleoclimate and Marine Geology and Geophysics, and the Department of Energy. The authors thank Jun Hu, Kyle Niezgoda, and Michelle Frazer for sharing the simulation output used to create figure . Part of this material is based upon work supported by the National Center for Atmospheric Research, which is a major facility sponsored by the National Science Foundation under Cooperative Agreement 1852977. A B acknowledges NASA Grants 80NSSC21K0939 and 80NSSC24K0676. A B, S D, and J N acknowledge NASA Grant 80NSSC20K0899. J C acknowledges NSF-OCE CAREER 1847791. S S acknowledges NSF-AGS 1805143 and NSF-OCE 2202794. A A acknowledges NSF-EAR 2002444 and PAGES DSS_114. This review paper was motivated by discussions of the US CLIVAR Working Group on Water Isotopes, which was jointly supported by NASA, NOAA, NSF programs in Paleoclimate and Marine Geology and Geophysics, and the Department of Energy. The authors thank Jun Hu, Kyle Niezgoda, and Michelle Frazer for sharing the simulation output used to create figure 2. Part of this material is based upon work supported by the National Center for Atmospheric Research, which is a major facility sponsored by the National Science Foundation under Cooperative Agreement 1852977. A B acknowledges NASA Grants 80NSSC21K0939 and 80NSSC24K0676. A B, S D, and J N acknowledge NASA Grant 80NSSC20K0899. J C acknowledges NSF-OCE CAREER 1847791. S S acknowledges NSF-AGS 1805143 and NSF-OCE 2202794. A A acknowledges NSF-EAR 2002444 and PAGES DSS_114.",
year = "2025",
month = mar,
day = "31",
doi = "10.1088/2752-5295/ada17b",
language = "English (US)",
volume = "4",
journal = "Environmental Research: Climate",
issn = "2752-5295",
publisher = "Institute of Physics",
number = "1",
}