The Cloud Radiative Response to Surface Warming Weakens Hydrological Sensitivity

Zachary McGraw; Lorenzo M. Polvani; Blaž Gasparini; Emily K. Van de Koot; Aiko Voigt

doi:10.1029/2024GL112368

The Cloud Radiative Response to Surface Warming Weakens Hydrological Sensitivity

Zachary McGraw (Korresp. Autor*in)
, Lorenzo M. Polvani
, Blaž Gasparini
, Emily K. Van de Koot
, Aiko Voigt

Institut für Meteorologie und Geophysik

Veröffentlichungen: Beitrag in Fachzeitschrift › Artikel › Peer Reviewed

Abstract

Precipitation is expected to increase in a warmer global climate, yet how sensitive precipitation is to warming depends on poorly constrained cloud radiative processes. Clouds respond to surface warming in ways that alter the atmosphere's ability to radiatively cool and hence form precipitation. Here we examine the links between cloud responses to warming, atmospheric radiative fluxes, and hydrological sensitivity in AMIP6 simulations. The clearest impacts come from high clouds, which reduce atmospheric radiative cooling as they rise in altitude in response to surface warming. Using cloud locking, we demonstrate that high cloud radiative changes weaken Earth's hydrological sensitivity to surface warming. The total impact of cloud radiative effects on hydrological sensitivity is halved by interactions between cloud and clear-sky radiative effects, yet is sufficiently large to be a major source of uncertainty in hydrological sensitivity.

Originalsprache	Englisch
Aufsatznummer	e2024GL112368
Fachzeitschrift	Geophysical Research Letters
Jahrgang	52
Ausgabenummer	2
DOIs	https://doi.org/10.1029/2024GL112368
Publikationsstatus	Veröffentlicht - 28 Jan. 2025

Fördermittel

LMP acknowledges funding from the US National Science Foundation to Columbia University (award 2335762). BG and AV acknowledge funding from the EU's Horizon 2020 research and innovation programme (Marie Sklodowska\u2010Curie grant 101025473). EV acknowledges funding from the UK Natural Environmental Research Council, Doctoral Training Partnership in Environmental Research (Grant NE/S007474/1). LMP acknowledges funding from the US National Science Foundation to Columbia University (award 2335762). BG and AV acknowledge funding from the EU's Horizon 2020 research and innovation programme (Marie Sklodowska-Curie grant 101025473). EV acknowledges funding from the UK Natural Environmental Research Council, Doctoral Training Partnership in Environmental Research (Grant NE/S007474/1).

UN SDGs

Dieser Output leistet einen Beitrag zu folgendem(n) Ziel(en) für nachhaltige Entwicklung

SDG 13 – Maßnahmen zum Klimaschutz

ÖFOS 2012

105205 Klimawandel
105206 Meteorologie

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abstract = "Precipitation is expected to increase in a warmer global climate, yet how sensitive precipitation is to warming depends on poorly constrained cloud radiative processes. Clouds respond to surface warming in ways that alter the atmosphere's ability to radiatively cool and hence form precipitation. Here we examine the links between cloud responses to warming, atmospheric radiative fluxes, and hydrological sensitivity in AMIP6 simulations. The clearest impacts come from high clouds, which reduce atmospheric radiative cooling as they rise in altitude in response to surface warming. Using cloud locking, we demonstrate that high cloud radiative changes weaken Earth's hydrological sensitivity to surface warming. The total impact of cloud radiative effects on hydrological sensitivity is halved by interactions between cloud and clear-sky radiative effects, yet is sufficiently large to be a major source of uncertainty in hydrological sensitivity.",

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AU - Voigt, Aiko

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AB - Precipitation is expected to increase in a warmer global climate, yet how sensitive precipitation is to warming depends on poorly constrained cloud radiative processes. Clouds respond to surface warming in ways that alter the atmosphere's ability to radiatively cool and hence form precipitation. Here we examine the links between cloud responses to warming, atmospheric radiative fluxes, and hydrological sensitivity in AMIP6 simulations. The clearest impacts come from high clouds, which reduce atmospheric radiative cooling as they rise in altitude in response to surface warming. Using cloud locking, we demonstrate that high cloud radiative changes weaken Earth's hydrological sensitivity to surface warming. The total impact of cloud radiative effects on hydrological sensitivity is halved by interactions between cloud and clear-sky radiative effects, yet is sufficiently large to be a major source of uncertainty in hydrological sensitivity.

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The Cloud Radiative Response to Surface Warming Weakens Hydrological Sensitivity

Abstract

Fördermittel

UN SDGs

ÖFOS 2012

Zugriff auf Dokument

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