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Sub-diurnal asymmetric warming has amplified atmospheric dryness since the 1980s

Ziqian Zhong, Hans W. Chen (), Aiguo Dai, Tianjun Zhou, Bin He and Bo Su
Additional contact information
Ziqian Zhong: Chalmers University of Technology
Hans W. Chen: Chalmers University of Technology
Aiguo Dai: University at Albany, State University of New York
Tianjun Zhou: Chinese Academy of Sciences
Bin He: Beijing Normal University
Bo Su: Beijing Normal University

Nature Communications, 2025, vol. 16, issue 1, 1-13

Abstract: Abstract Rising atmospheric vapor pressure deficit (VPD)—a measure of atmospheric dryness, defined as the difference between saturated vapor pressure (SVP) and actual vapor pressure (AVP)—has been linked to increasing daily mean near-surface air temperatures since the 1980s. However, it remains unclear whether the faster increases in daily maximum temperature (Tmax) relative to daily minimum temperature (Tmin) have contributed to rising VPD. Here, we show that the faster rise in Tmax compared with Tmin over land has intensified VPD from 1980 to 2023. This sub-diurnal asymmetric warming has driven a larger SVP increase than would occur under uniform temperature rise, while AVP is more strongly influenced by Tmin. Using reanalysis data, we estimate that asymmetric warming has contributed an additional ~18% to the increase in global land VPD. Sub-daily station observations corroborate this pattern, with asymmetric warming accounting for ~30% of VPD intensification across all stations. Our findings indicate that sub-diurnal asymmetric warming has substantially amplified global warming’s effect on atmospheric dryness over the past four decades, with significant implications for terrestrial water availability and carbon cycling.

Date: 2025
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DOI: 10.1038/s41467-025-63672-z

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