Better calibration of cloud parameterizations and subgrid effects increases the fidelity of the E3SM Atmosphere Model version 1

Ma, Po‐Lun; Harrop, Bryce E.; Larson, Vincent E.; Neale, Richard; Gettelman, Andrew; Morrison, Hugh; Wang, Hailong; Zhang, Kai; Klein, Stephen A.; Zelinka, Mark D.; Zhang, Yuying; Qian, Yun; Yoon, Jin‐Ho; Jones, C. R.; Huang, Meng; Tai, Sheng‐Lun; Singh, Balwinder; Bogenschutz, Peter A.; Zheng, Xue; Lin, Wuyin; Quaas, Johannes; Chepfer, Hélène; Brunke, Michael A.; Zeng, Xubin; Mülmenstädt, J.; Hagos, Samson; Zhang, Zhibo; Song, Hua; Liu, Xiaohong; Pritchard, Michael S.; Wan, Hui; Wang, Jingyu; Tang, Qi; Caldwell, Peter; Fan, Jiwen; Berg, Larry K.; Fast, Jerome D.; Taylor, Mark A.; Golaz, Jean‐Christophe; Xie, Shaocheng; Rasch, Philip J.; Leung, L. R.

doi:10.5194/gmd-15-2881-2022

Cited by 30 publications

(47 citation statements)

References 141 publications

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“…Conversely, while recalibrated parameters for ZM scheme also increase ice cloud and decrease liquid cloud, simulated total cloud cover is increased as shown in Figure 8d. Reduced convective autoconversion efficiency and decreased ice particle size detrained from deep convection probably prolong the lifetime of ice clouds (Ma et al., 2022). Note that the decrease of liquid cloud due to the modified WBF process scaling factor and ZM tuning is largely canceled out by the introductions of the new dCAPE_ULL trigger and the minimum CDNC.…”

Section: Model Sensitivity Experimentsmentioning

confidence: 99%

Cloud Phase Simulation at High Latitudes in EAMv2: Evaluation Using CALIPSO Observations and Comparison With EAMv1

et al. 2022

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Clouds play an essential role in global climate through interactions with radiation and hydrological cycle. The extensive coverage and strong radiative effects make clouds an important modulator of the energy budget at the surface and top of the atmosphere. Cloud radiative effects are controlled by cloud optical depth and other optical properties that are closely related to cloud microphysical properties such as amount, size, shape, and thermodynamic phase of cloud hydrometeors (Curry & Ebert, 1992;Curry et al., 1996;Shupe & Intrieri, 2004). Cloud albedo is more sensitive to variations in cloud liquid water than cloud ice water. The shortwave radiative cooling effect due to liquid water usually dominates the net cloud radiative effect in mixed-phase clouds, highlighting the importance of cloud thermodynamic phase on cloud radiative forcing (Sun & Shine, 1994). In addition, differences in microphysical properties between liquid and ice are critical for global precipitation. Satellite observations have demonstrated that most of the Earth's precipitation originates from the ice phase and mixed-phase cloud processes, while warm rain mechanisms are more critical for precipitation over tropical and subtropical oceans (Field & Heymsfield, 2015;Heymsfield et al., 2020;Mülmenstädt et al., 2015). The distinct roles of cloud liquid and cloud ice on precipitation formation make cloud phase one of the key factors influencing the hydrological cycle in the Earth system. Moreover, the cloud liquid and ice microphysical properties in the present-day climate can also have a significant impact on the Arctic amplification (Middlemas et al., 2020) and future global climate change (Bjordal et al., 2020;Lohmann & Neubauer, 2018;Tsushima et al., 2006). For example, it has been found that the predicted Arctic amplification strength is highly sensitive to the ice particle size and number concentration of ice nucleating particles in the present-day environment (Tan & Storelvmo, 2019;Tan et al., 2022). Across the globe, if clouds in the present-day climate have a lower ice water amount, the phase transition from ice to liquid would be less significant in a future warmer climate, which would result in a weaker

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Section: Model Sensitivity Experimentsmentioning

confidence: 99%

Cloud Phase Simulation at High Latitudes in EAMv2: Evaluation Using CALIPSO Observations and Comparison With EAMv1

et al. 2022

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“…6. These parameterization changes were applied during the E3SMv1 development and some of them have been further tuned for an alternate configuration of E3SM (Ma et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Note that the 0.2 m s −1 lower bound might be too high to be applied to all conditions, but removing it in E3SMv1 will degrade the cloud simulation if the model is not further tuned. In newer versions of E3SM(Ma et al, 2022;Golaz et al, 2022), this lower bound is reduced to 0.1 m s −1 , in combination with other tunings in the cloud and turbulence parameterizations.2 CLUBB calculates the vertical diffusion transport of other quantities, including water vapor, cloud hydrometeors (excluding cloud droplet number), and other trace gases.…”

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confidence: 99%

Effective radiative forcing of anthropogenic aerosols in E3SM version 1: historical changes, causality, decomposition, and parameterization sensitivities

Zhang¹,

Zhang²,

Wan³

et al. 2022

Atmos. Chem. Phys.

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Abstract. The effective radiative forcing of anthropogenic aerosols (ERFaer) is an important measure of the anthropogenic aerosol effects simulated by a global climate model. Here we analyze ERFaer simulated by the E3SM version 1 (E3SMv1) atmospheric model using both century-long free-running atmosphere–land simulations and short nudged simulations. We relate the simulated ERFaer to characteristics of the aerosol composition and optical properties, and we evaluate the relationships between key aerosol and cloud properties. In terms of historical changes from the year 1870 to 2014, our results show that the global mean anthropogenic aerosol burden and optical depth increase during the simulation period as expected, but the regional averages show large differences in the temporal evolution. The largest regional differences are found in the emission-induced evolution of the burden and optical depth of the sulfate aerosol: a strong decreasing trend is seen in the Northern Hemisphere high-latitude region after around 1970, while a continued increase is simulated in the tropics. The relationships between key aerosol and cloud properties (relative changes between pre-industrial and present-day conditions) also show evident changes after 1970, diverging from the linear relationships exhibited for the period of 1870–1969. In addition to the regional differences in the simulated relationships, a reduced sensitivity in cloud droplet number and other cloud properties to aerosol perturbations is seen when the aerosol perturbation is large. Consequently, the global annual mean ERFaer magnitude does not increase after around 1970. The ERFaer in E3SMv1 is relatively large compared to the recently published multi-model estimates; the primary reason is the large indirect aerosol effect (i.e., through aerosol–cloud interactions). Compared to other models, E3SMv1 features large relative changes in the cloud droplet effective radius in response to aerosol perturbations. Large sensitivity is also seen in the liquid cloud optical depth, which is determined by changes in both the effective radius and liquid water path. Aerosol-induced changes in liquid and ice cloud properties in E3SMv1 are found to have a strong correlation, as the evolution of anthropogenic sulfate aerosols affects both the liquid cloud formation and the homogeneous ice nucleation in cirrus clouds (that causes a large effect on longwave ERFaer). As suggested by a previous study, the large ERFaer appears to be one of the reasons why the model cannot reproduce the observed global mean temperature evolution in the second half of the 20th century. Sensitivity simulations are performed to understand which parameterization and/or parameter changes have a large impact on the simulated ERFaer. The ERFaer estimates in E3SMv1 for the shortwave and longwave components are sensitive to the parameterization changes in both liquid and ice cloud processes. When the parameterization of ice cloud processes is modified, the top-of-model forcing changes in the shortwave and longwave components largely offset each other, so the net effect is negligible. This suggests that, to reduce the magnitude of the net ERFaer, it would be more effective to reduce the anthropogenic aerosol effect through liquid or mixed-phase clouds.

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“…The weaker turbulence coming from CLUBB as used in CAM6 might be rectified from a revision of its parameters. Ma et al (2021) recently performed a retuning of the parameters used to define the width of the bivariate normal PDFs as well as the effects of the turbulence skewness Sk w in the determination of quantities in the development of the E3SM EAMv2. This retuning was performed using theoretical considerations to improve the simulation of mostly subtropical stratocumulus decks.…”

Section: Discussionmentioning

confidence: 99%

“…Both of these models use the higher-order scheme CLUBB that unifies boundary layer turbulence, shallow convection, and cloud macrophysics. The main difference in the CLUBB implementation between these two models is that EAMv2 recently underwent a retuning of the parameters used to define the width of the binormal PDFs as well as the effects of the turbulence skewness Sk w in the determination of quantities (Ma et al, 2021). This retuning was undertaken to improve the simulation of the subtropical stratocumulus decks.…”

Section: Methodsmentioning

confidence: 99%

Aircraft Observations of Turbulence in Cloudy and Cloud‐Free Boundary Layers Over the Western North Atlantic Ocean From ACTIVATE and Implications for the Earth System Model Evaluation and Development

et al. 2022

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Clouds substantially impact the Earth system's radiative balance (Brunke et al., 2010). Their radiative impact on the Earth's energy balance is one of the largest uncertainties in the Earth system (Boucher et al., 2013). There has long been a large spread in simulated cloud feedbacks (Bony & Dufresne, 2005), resulting from a high uncertainty in the simulation of clouds in Earth system models (ESMs) (Bony et al., 2006). This uncertainty stems from a wide spread in the simulation of cloud characteristics like liquid and ice water paths (Kormurcu et al., 2014).Cloud simulation uncertainty also stems from the representation of droplet activation and ice nucleation (Choi et al., 2010(Choi et al., , 2014. Cloud droplets form around aerosols that have been activated called cloud condensation nuclei (CCN). This connection between aerosols and cloud formation is one critical aspect of aerosol-cloud interactions (ACI). There is the long recognized indirect effect of a decrease in cloud droplet radius owing to increased cloud droplet number concentration (at fixed liquid water content) with an increase in aerosol concentration. The increased cloud droplet number results in higher cloud albedo (Twomey, 1977) and decreased precipitation efficiency, which is speculated to increase cloud lifetime (Albrecht, 1989) as long as the air above-cloud is humid enough (Ackerman et al., 2004).Turbulent eddies strongly influence ACI and are critical to the maintenance of boundary layer clouds (Seinfeld et al., 2016). The strength of these eddies below clouds is characterized by turbulence kinetic energy (TKE), which determines updraft velocity at cloud base (Zhang et al., 2021). Updraft velocity controls the amount of

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Better calibration of cloud parameterizations and subgrid effects increases the fidelity of the E3SM Atmosphere Model version 1

Cited by 30 publications

References 141 publications

Cloud Phase Simulation at High Latitudes in EAMv2: Evaluation Using CALIPSO Observations and Comparison With EAMv1

Cloud Phase Simulation at High Latitudes in EAMv2: Evaluation Using CALIPSO Observations and Comparison With EAMv1

Effective radiative forcing of anthropogenic aerosols in E3SM version 1: historical changes, causality, decomposition, and parameterization sensitivities

Aircraft Observations of Turbulence in Cloudy and Cloud‐Free Boundary Layers Over the Western North Atlantic Ocean From ACTIVATE and Implications for the Earth System Model Evaluation and Development

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