Surface warming and wetting due to methane’s long-wave radiative effects muted by short-wave absorption

Although greenhouse gases absorb primarily long-wave radiation, they also absorb short-wave radiation. Recent studies have highlighted the importance of methane short-wave absorption, which enhances its stratospherically adjusted radiative forcing by up to ~ 15%. The corresponding climate impacts, h...

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Published in:Nature geoscience 2023-04, Vol.16 (4), p.314-320
Main Authors: Allen, Robert J., Zhao, Xueying, Randles, Cynthia A., Kramer, Ryan J., Samset, Bjørn H., Smith, Christopher J.
Format: Article
Language:English
Subjects:
704/106/694/1108
704/106/694/2739
704/106/694/682
Absorption
Climate
Climate change
Clouds
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Emissions
Gas absorption
Gases
Geochemistry
Geology
Geophysics/Geodesy
Global warming
Greenhouse effect
Greenhouse gases
High level clouds
Long wave radiation
Methane
Methane emissions
Outgoing long-wave radiation
Precipitation
Radiation
Radiation absorption
Radiation-cloud interactions
Radiative forcing
Relative humidity
Short wave radiation
Solar heating
Surface chemistry
Surface temperature
Wave reflection
Wetting
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description Although greenhouse gases absorb primarily long-wave radiation, they also absorb short-wave radiation. Recent studies have highlighted the importance of methane short-wave absorption, which enhances its stratospherically adjusted radiative forcing by up to ~ 15%. The corresponding climate impacts, however, have been only indirectly evaluated and thus remain largely unquantified. Here we present a systematic, unambiguous analysis using one model and separate simulations with and without methane short-wave absorption. We find that methane short-wave absorption counteracts ~30% of the surface warming associated with its long-wave radiative effects. An even larger impact occurs for precipitation as methane short-wave absorption offsets ~60% of the precipitation increase relative to its long-wave radiative effects. The methane short-wave-induced cooling is due largely to cloud rapid adjustments, including increased low-level clouds, which enhance the reflection of incoming short-wave radiation, and decreased high-level clouds, which enhance outgoing long-wave radiation. The cloud responses, in turn, are related to the profile of atmospheric solar heating and corresponding changes in temperature and relative humidity. Despite our findings, methane remains a potent contributor to global warming, and efforts to reduce methane emissions are vital for keeping global warming well below 2 °C above preindustrial values. Climate simulations suggest that the contribution of methane to climate warming and wetting due to absorption of long-wave radiation is partially counteracted by short-wave absorption.
doi_str_mv 10.1038/s41561-023-01144-z
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subjects 704/106/694/1108
704/106/694/2739
704/106/694/682
Absorption
Climate
Climate change
Clouds
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Emissions
Gas absorption
Gases
Geochemistry
Geology
Geophysics/Geodesy
Global warming
Greenhouse effect
Greenhouse gases
High level clouds
Long wave radiation
Methane
Methane emissions
Outgoing long-wave radiation
Precipitation
Radiation
Radiation absorption
Radiation-cloud interactions
Radiative forcing
Relative humidity
Short wave radiation
Solar heating
Surface chemistry
Surface temperature
Wave reflection
Wetting
title Surface warming and wetting due to methane’s long-wave radiative effects muted by short-wave absorption
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