Water sources and land capacitor effects stimulate observed summer Arctic moistening and warming

Ian Baxter; Qinghua Ding; Thomas Ballinger; Hailong Wang; Marika Holland; Hailan Wang; Zhe Li; Yutian Wu; Nicole Feldl; Jennifer E. Kay; Bin Guan; Jiang Zhu

doi:10.1038/s43247-025-03000-x

Water sources and land capacitor effects stimulate observed summer Arctic moistening and warming

Ian Baxter
, Qinghua Ding
, Thomas Ballinger
, Hailong Wang
, Marika Holland
, Hailan Wang
, Zhe Li
, Yutian Wu
, Nicole Feldl
, Jennifer E. Kay
, Bin Guan
, Jiang Zhu

University of California at Santa Barbara
University of Alaska Fairbanks
Pacific Northwest National Laboratory
National Center for Atmospheric Research
National Oceanic and Atmospheric Administration
Columbia University
University of California at Santa Cruz
University of Colorado Boulder
University of California
California Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The primary sources of recent summer Arctic moistening trends in reanalysis are uncertain, hindering attribution of observed Arctic warming due to radiative effects from water vapor changes. Here, we use a combined online numerical water tracer and circulation nudging approach in the Community Earth System Model to track the sources of water vapor beyond its initial sources. Trends in boreal summer large-scale circulation have driven moistening of the Arctic over recent decades, having a large impact on the Arctic radiative budget, accounting for 94% of the strengthening water vapor radiative feedback. We identify two key regions supplying the Arctic water vapor feedback: Northeast North America and western/central Eurasia. In both regions, anticyclonic circulations over the southwest Atlantic and eastern Europe move moisture from the tropical oceans poleward to high latitude land through precipitation in winter and spring. During summer, evapotranspiration over land releases this water vapor, and it is transported by winds into the Arctic. We refer to this sequence of terrestrial moisture storage and release as the land capacitor effect. Thus, the impacts of circulation changes on poleward moisture transport and land-atmosphere interactions over high latitudes represent the underlying mechanisms of the recent moistening and warming in the Arctic.

Original language	English
Article number	1027
Number of pages	13
Journal	Communications Earth and Environment
Volume	6
Issue number	1
DOIs	https://doi.org/10.1038/s43247-025-03000-x
State	Published - Dec 3 2025
Externally published	Yes

Funding

This study is supported by NSF Arctic System Science awards OPP 2246601 and OPP 2246600 and Climate Variability & Predictability (NA23OAR4310273) programs as part of NOAA's Climate Program Office. H.W. was supported by the U.S. Department of Energy (DOE), Office of Science, Office of Biological and Environmental Research, Regional and Global Model Analysis program area. The Pacific Northwest National Laboratory (PNNL) is operated for DOE by Battelle Memorial Institute under contract DE-AC05-76RLO1830. NF was supported by DOE Award DE-SC0023070. JEK acknowledges support from NSF 2233420. BG was supported by NASA grants 80NSSC20K1344, 80NSSC21K1007, and 80NSSC22K0926, and the California Department of Water Resources.

Funders	Funder number
NSF Office of Polar Programs (OPP) Arctic System Science OPP 2246601 and OPP
United States Department of Commerce \| NOAA \| Climate Program Office (NOAA Climate Program Office)	NA23OAR4310273

Keywords

Sea-ice
Polar amplification
Global precipitation
Hydrological cycle
Climate feedbacks
Air-temperature
Surface
Transport
Evaporation
Trends

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10.1038/s43247-025-03000-x

Cite this

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title = "Water sources and land capacitor effects stimulate observed summer Arctic moistening and warming",

abstract = "The primary sources of recent summer Arctic moistening trends in reanalysis are uncertain, hindering attribution of observed Arctic warming due to radiative effects from water vapor changes. Here, we use a combined online numerical water tracer and circulation nudging approach in the Community Earth System Model to track the sources of water vapor beyond its initial sources. Trends in boreal summer large-scale circulation have driven moistening of the Arctic over recent decades, having a large impact on the Arctic radiative budget, accounting for 94\% of the strengthening water vapor radiative feedback. We identify two key regions supplying the Arctic water vapor feedback: Northeast North America and western/central Eurasia. In both regions, anticyclonic circulations over the southwest Atlantic and eastern Europe move moisture from the tropical oceans poleward to high latitude land through precipitation in winter and spring. During summer, evapotranspiration over land releases this water vapor, and it is transported by winds into the Arctic. We refer to this sequence of terrestrial moisture storage and release as the land capacitor effect. Thus, the impacts of circulation changes on poleward moisture transport and land-atmosphere interactions over high latitudes represent the underlying mechanisms of the recent moistening and warming in the Arctic.",

keywords = "Sea-ice, Polar amplification, Global precipitation, Hydrological cycle, Climate feedbacks, Air-temperature, Surface, Transport, Evaporation, Trends",

author = "Ian Baxter and Qinghua Ding and Thomas Ballinger and Hailong Wang and Marika Holland and Hailan Wang and Zhe Li and Yutian Wu and Nicole Feldl and Kay, \{Jennifer E.\} and Bin Guan and Jiang Zhu",

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doi = "10.1038/s43247-025-03000-x",

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AU - Baxter, Ian

AU - Ding, Qinghua

AU - Ballinger, Thomas

AU - Wang, Hailong

AU - Holland, Marika

AU - Wang, Hailan

AU - Li, Zhe

AU - Wu, Yutian

AU - Feldl, Nicole

AU - Kay, Jennifer E.

AU - Guan, Bin

AU - Zhu, Jiang

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/12/3

Y1 - 2025/12/3

N2 - The primary sources of recent summer Arctic moistening trends in reanalysis are uncertain, hindering attribution of observed Arctic warming due to radiative effects from water vapor changes. Here, we use a combined online numerical water tracer and circulation nudging approach in the Community Earth System Model to track the sources of water vapor beyond its initial sources. Trends in boreal summer large-scale circulation have driven moistening of the Arctic over recent decades, having a large impact on the Arctic radiative budget, accounting for 94% of the strengthening water vapor radiative feedback. We identify two key regions supplying the Arctic water vapor feedback: Northeast North America and western/central Eurasia. In both regions, anticyclonic circulations over the southwest Atlantic and eastern Europe move moisture from the tropical oceans poleward to high latitude land through precipitation in winter and spring. During summer, evapotranspiration over land releases this water vapor, and it is transported by winds into the Arctic. We refer to this sequence of terrestrial moisture storage and release as the land capacitor effect. Thus, the impacts of circulation changes on poleward moisture transport and land-atmosphere interactions over high latitudes represent the underlying mechanisms of the recent moistening and warming in the Arctic.

AB - The primary sources of recent summer Arctic moistening trends in reanalysis are uncertain, hindering attribution of observed Arctic warming due to radiative effects from water vapor changes. Here, we use a combined online numerical water tracer and circulation nudging approach in the Community Earth System Model to track the sources of water vapor beyond its initial sources. Trends in boreal summer large-scale circulation have driven moistening of the Arctic over recent decades, having a large impact on the Arctic radiative budget, accounting for 94% of the strengthening water vapor radiative feedback. We identify two key regions supplying the Arctic water vapor feedback: Northeast North America and western/central Eurasia. In both regions, anticyclonic circulations over the southwest Atlantic and eastern Europe move moisture from the tropical oceans poleward to high latitude land through precipitation in winter and spring. During summer, evapotranspiration over land releases this water vapor, and it is transported by winds into the Arctic. We refer to this sequence of terrestrial moisture storage and release as the land capacitor effect. Thus, the impacts of circulation changes on poleward moisture transport and land-atmosphere interactions over high latitudes represent the underlying mechanisms of the recent moistening and warming in the Arctic.

KW - Sea-ice

KW - Polar amplification

KW - Global precipitation

KW - Hydrological cycle

KW - Climate feedbacks

KW - Air-temperature

KW - Surface

KW - Transport

KW - Evaporation

KW - Trends

UR - https://www.scopus.com/pages/publications/105025442777

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ER -

Water sources and land capacitor effects stimulate observed summer Arctic moistening and warming

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Keywords

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