Observational constraints on mixed-phase clouds imply higher climate sensitivity

Tan, Ivy; Storelvmo, Trude; Zelinka, Mark D.

doi:10.1126/science.aad5300

Cited by 398 publications

(525 citation statements)

References 36 publications

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“…ECS ranges between 1.8 and 2.8 K in all our simulations ( Table 3) and with that lies on the lower side of the range of ECS estimated in the last IPCC report (Collins et al, 5 2013;Flato et al, 2013) and from CMIP5 models . Similar to Tan et al (2016), ECS increases by ∼ 30% when increasing SLF from almost zero to one (simulations ALL_ICE and ALL_LIQ in this paper vs. Low-SLF and High-SLF in Tan et al (2016) Figure 4. Effective radiative forcing due to aerosol-radiation and aerosol-cloud interactions (ERFari+aci) and equilibrium climate sensitivity for the various sensitivity simulations described in Table 1. low SLF.…”

Section: Equilibrium Climate Sensitivitymentioning

confidence: 50%

“…Since in ECHAM6-HAM2 this is only the case in simulation ALL_ICE, this is the only simulation with a distinctively lower ECS. In CAM5, too much shortwave radiation is absorbed over the Southern Ocean in their present-day climate (Kay et al, 2016), which explains why ECS is also sensitive to an increase in SLF in the study by Tan et al (2016).…”

Section: Equilibrium Climate Sensitivitymentioning

confidence: 99%

“…• C (simulation ALL_LIQ) similar to what has been done in Tan et al (2016) and Lohmann (2002). Another aspect to the possible impact of ice on ERFari+aci is the nucleation in cirrus clouds.…”

Section: Model Set-up and Experimentsmentioning

confidence: 99%

“…If mixed-phase clouds in the current climate contain too few supercooled cloud 5 droplets, too much ice will change to liquid water in a warmer climate. As shown by Tan et al (2016), this overestimates the negative cloud phase feedback and underestimates ECS in the CAM global climate model (GCM). Here we are using the newest version of the ECHAM6-HAM2 GCM to investigate the importance of mixed-phase clouds for ECS.…”

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confidence: 99%

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The importance of mixed-phase clouds for climate sensitivity in the global aerosol-climate model ECHAM6-HAM2

Lohmann¹,

Neubauer²

2018

Preprint

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Abstract. Clouds are important in the climate system because of their large influence on the radiation budget. On the one hand, they scatter solar radiation and with that cool the climate. On the other hand, they absorb and re-emit terrestrial radiation, which causes a warming. How clouds change in a warmer climate is one of the largest uncertainties for the equilibrium climate sensitivity (ECS). While a large spread in the cloud feedback arises from low-level clouds, it was recently shown that also mixed-phase clouds are important for ECS. If mixed-phase clouds in the current climate contain too few supercooled cloud 5 droplets, too much ice will change to liquid water in a warmer climate. As shown by Tan et al. (2016), this overestimates the negative cloud phase feedback and underestimates ECS in the CAM global climate model (GCM). Here we are using the newest version of the ECHAM6-HAM2 GCM to investigate the importance of mixed-phase clouds for ECS.Although we also considerably underestimate the fraction of supercooled liquid water globally in the reference version of ECHAM6-HAM2 GCM, we do not obtain increases in ECS in simulations with more supercooled liquid water in the present-

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Section: Equilibrium Climate Sensitivitymentioning

confidence: 50%

Section: Equilibrium Climate Sensitivitymentioning

confidence: 99%

Section: Model Set-up and Experimentsmentioning

confidence: 99%

mentioning

confidence: 99%

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The importance of mixed-phase clouds for climate sensitivity in the global aerosol-climate model ECHAM6-HAM2

Lohmann¹,

Neubauer²

2018

Preprint

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“…Many of the major biases in global climate models are related to processes that are central in cold air outbreaks, such as vertical mixing in the boundary layer and mixed-phase cloud microphysics [Tsushima et al, 2006;Gettelman et al, 2010;Pithan et al, 2014;Tan et al, 2016].…”

Section: Introductionmentioning

confidence: 99%

The “Grey Zone” cold air outbreak global model intercomparison: A cross evaluation using large‐eddy simulations

Tomassini

Field

Honnert

et al. 2017

J Adv Model Earth Syst

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A stratocumulus‐to‐cumulus transition as observed in a cold air outbreak over the North Atlantic Ocean is compared in global climate and numerical weather prediction models and a large‐eddy simulation model as part of the Working Group on Numerical Experimentation “Grey Zone” project. The focus of the project is to investigate to what degree current convection and boundary layer parameterizations behave in a scale‐adaptive manner in situations where the model resolution approaches the scale of convection. Global model simulations were performed at a wide range of resolutions, with convective parameterizations turned on and off. The models successfully simulate the transition between the observed boundary layer structures, from a well‐mixed stratocumulus to a deeper, partly decoupled cumulus boundary layer. There are indications that surface fluxes are generally underestimated. The amount of both cloud liquid water and cloud ice, and likely precipitation, are under‐predicted, suggesting deficiencies in the strength of vertical mixing in shear‐dominated boundary layers. But also regulation by precipitation and mixed‐phase cloud microphysical processes play an important role in the case. With convection parameterizations switched on, the profiles of atmospheric liquid water and cloud ice are essentially resolution‐insensitive. This, however, does not imply that convection parameterizations are scale‐aware. Even at the highest resolutions considered here, simulations with convective parameterizations do not converge toward the results of convection‐off experiments. Convection and boundary layer parameterizations strongly interact, suggesting the need for a unified treatment of convective and turbulent mixing when addressing scale‐adaptivity.

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Insights from a refined decomposition of cloud feedbacks

Zelinka

Zhou

Klein

2016

Geophysical Research Letters

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171

191

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Decomposing cloud feedback into components due to changes in several gross cloud properties provides valuable insights into its physical causes. Here we present a refined decomposition that separately considers changes in free tropospheric and low cloud properties, better connecting feedbacks to individual governing processes and avoiding ambiguities present in a commonly used decomposition. It reveals that three net cloud feedback components are robustly nonzero: positive feedbacks from increasing free tropospheric cloud altitude and decreasing low cloud cover and a negative feedback from increasing low cloud optical depth. Low cloud amount feedback is the dominant contributor to spread in net cloud feedback but its anticorrelation with other components damps overall spread. The ensemble mean free tropospheric cloud altitude feedback is roughly 60% as large as the standard cloud altitude feedback because it avoids aliasing in low cloud reductions. Implications for the “null hypothesis” climate sensitivity from well‐understood and robustly simulated feedbacks are discussed.

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Observational constraints on mixed-phase clouds imply higher climate sensitivity

Cited by 398 publications

References 36 publications

The importance of mixed-phase clouds for climate sensitivity in the global aerosol-climate model ECHAM6-HAM2

The importance of mixed-phase clouds for climate sensitivity in the global aerosol-climate model ECHAM6-HAM2

The “Grey Zone” cold air outbreak global model intercomparison: A cross evaluation using large‐eddy simulations

Insights from a refined decomposition of cloud feedbacks

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