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1. The Impact of Rotation on Tropical Climate, the Hydrologic Cycle, and Climate Sensitivity

   https://doi.org/10.1029/2023GL105850  

   Silvers, Levi G; Stansfield, Alyssa M; Reed, Kevin A (March 2024, Geophysical Research Letters)

   Abstract This work explores the impact of rotation on tropical convection and climate. As our starting point, we use the RCEMIP experiments as control simulations and run additional simulations with rotation. Compared to radiative convective equilibrium (RCE) experiments, rotating RCE (RRCE) experiments have a more stable and humid atmosphere with higher precipitation rates. The intensity of the overturning circulation decreases, water vapor is cycled through the troposphere at a slower rate, the subsidence fraction decreases, and the climate sensitivity increases. Several of these changes can be attributed to an increased flux of latent and sensible heat that results from an increase of near‐surface wind speed with rotation shortly after model initialization. The increased climate sensitivity results from changes of both the longwave cloud radiative effect and the longwave clear‐sky radiative fluxes. This work demonstrates the sensitivity of atmospheric humidity and surface fluxes of moisture and temperature to rotation. 

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2. RCEMIP‐ACI: Aerosol‐Cloud Interactions in a Multimodel Ensemble of Radiative‐Convective Equilibrium Simulations

   https://doi.org/10.1029/2025MS005141  

   Dagan, Guy; van_den_Heever, Susan C; Stier, Philip; Abbott, Tristan H; Barthlott, Christian; Chaboureau, Jean‐Pierre; Fan, Jiwen; de_Roode, Stephan; Gasparini, Blaž; Hoose, Corinna; et al (November 2025, Journal of Advances in Modeling Earth Systems)

   Abstract Aerosol‐cloud interactions are a persistent source of uncertainty in climate research. This study presents findings from a model intercomparison project examining the impact of aerosols on clouds and climate in convection‐permitting radiative‐convective equilibrium (RCE) simulations. Specifically, 11 different modeling teams conducted RCE simulations under varying aerosol concentrations, domain configurations, and sea surface temperatures (SSTs). We analyze the response of domain‐mean cloud and radiative properties to imposed aerosol concentrations across different SSTs. Additionally, we explore the potential impact of aerosols on convective aggregation and large‐scale circulation in large‐domain simulations. The results reveal that the cloud and radiative responses to aerosols vary substantially across models. However, a common trend across models, SSTs, and domain configurations is that increased aerosol loading tends to suppress warm rain formation, enhance cloud water content in the mid‐troposphere, and consequently increase mid‐tropospheric humidity and upper‐tropospheric temperature, thereby impacting static stability. The warming of the upper troposphere can be attributed to reduced lateral entrainment effects due to the higher environmental humidity in the mid‐troposphere. However, models do not agree on aerosol impacts on convective updraft velocity based on the preliminary examination of high‐percentiles of vertical velocity at a single mid‐troposheric layer (500 hPa). In large‐domain simulations, where convection tends to self‐organize, aerosol loading does not consistently influence self‐organization but tends to reduce the intensity of large‐scale circulation forming between convective clusters and dry regions. This reduction in circulation intensity can be explained by the increase in static stability due to the upper tropospheric warming. 

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3. The Vertical Profile of Radiative Cooling and Lapse Rate in a Warming Climate

   https://doi.org/10.1175/JCLI-D-21-0861.1  

   Hartmann, Dennis L.; Dygert, Brittany D.; Blossey, Peter N.; Fu, Qiang; Sokol, Adam B. (June 2022, Journal of Climate)

   Abstract The vertical profile of clear-sky radiative cooling places important constraints on the vertical structure of convection and associated clouds. Simple theory using the cooling-to-space approximation is presented to indicate that the cooling rate in the upper troposphere should increase with surface temperature. The theory predicts how the cooling rate depends on lapse rate in an atmosphere where relative humidity remains approximately a fixed function of temperature. Radiative cooling rate is insensitive to relative humidity because of cancellation between the emission and transmission of radiation by water vapor. This theory is tested with one-dimensional radiative transfer calculations and radiative-convective equilibrium simulations. For climate simulations that produce an approximately moist adiabatic lapse rate, the radiative cooling profile becomes increasingly top-heavy with increasing surface temperature. If the temperature profile warms more slowly than a moist adiabatic profile in mid-troposphere, then the cooling rate in the upper troposphere is reduced and that in the lower troposphere is increased. This has important implications for convection, clouds and associated deep and shallow circulations. 

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4. Aerosol interactions with deep convective clouds

   https://doi.org/10.1016/B978-0-12-819766-0.00001-8  

   Fan, Jiwen; Li, Zhanqing (January 2022, Elsevier)

   Deep convective clouds (DCCs) are associated with the vertical ascent of air from the lower to the upper atmosphere. They appear in various forms such as thunderstorms, supercells, and squall lines. These convective systems play important roles in the hydrological cycle, Earth’s radiative budget, and the general circulation of the atmosphere. Changes in aerosol (both cloud condensation nuclei and ice-nucleating particles) affect cloud microphysics and dynamics, and thereby influence convective intensity, precipitation, and the radiative effects of deep clouds and their cirrus anvils. However, the very complex dynamics and cloud microphysics of DCCs means that many of these processes are not yet accurately quantified in observations and models. This chapter outlines the main ways in which changes in aerosol affect the microphysical, dynamical, and radiative properties of DCCs. Aerosol interactions with DCCs depend on aerosol properties, storm dynamics, and meteorological conditions. When aerosol particles are light-absorbing, such as soot from industry or biomass burning, the aerosol radiative effects can alter the meteorological conditions under which DCCs form. These radiative effects modify temperature profiles and planetary boundary layer heights, thus changing atmospheric stability and circulation, and affecting the onset and development of DCCs. These large-scale effects, such as the effect of anthropogenic aerosol on the East and South Asian monsoons, can be simulated in coarse-resolution models. These processes are described in Chapter 13. This chapter is concerned with aerosol interactions with DCC systems ranging from individual clouds to mesoscale convective systems. Increases in cloud condensation nuclei (CCN) can enhance cloud droplet number concentrations and decrease droplet sizes, thereby narrowing the droplet size spectrum. For DCCs, a narrowed droplet size spectrum suppresses warm rain formation (rain derived from non-ice-phase processes), allowing the transport of more, smaller droplets to altitudes below 0°C. This may result in (i) freezing of more supercooled water, thereby enhancing latent heating from icerelated microphysical processes and invigorating storms (ice-phase invigoration); (ii) modification of ice-related microphysical processes, which changes cold pools, precipitation rates, and hailstone frequency and size; (iii) expansion of the mixed-phase zone and decreases in the cloud glaciation temperature; and (iv) slowing down of cloud dissipation, resulting in larger cloud cover and cloud depth in the stratiform and anvil regions due to numerous smaller ice particles. The increased cloud cover and cloud depth constitute an influence of aerosol on the cloud radiative effect. Reduced diurnal temperature variation has been observed and simulated as a result of enhanced daytime cooling and nighttime warming by expanded anvil cloud area in polluted environments. However, the global radiative effect of aerosol interactions with DCCs remains to be quantified. 

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5. Radiative–Convective Equilibrium over an Idealized Land Surface with Fixed Soil Moisture

   https://doi.org/10.1175/JCLI-D-24-0438.1  

   Tang, Lois I; McColl, Kaighin A (November 2025, Journal of Climate)

   Abstract Radiative–convective equilibrium (RCE) is an idealized model of the atmosphere in which surface fluxes exactly balance radiative cooling. While recent work has shown RCE over land is a reasonable first-order model of continental climate, previous RCE studies have mainly focused on ocean surfaces. Unlike the ocean, the land surface has limited water and a low heat capacity. Here, we use theory and simulations to understand RCE over an idealized land surface with fixed soil moisture, a logical next step in the land climate model hierarchy. The fixed soil moisture case is also relevant to irrigated areas, groundwater-fed ecosystems, and broader debates about potential evapotranspiration (PET), aridity, and their changes in a warming world. We derive a parsimonious gray gas theory that reproduces major aspects of cloud-permitting simulations of RCE over an idealized land surface and permits analytic solutions for several special cases. Over fixed dry surfaces, the theory shows that hydrological sensitivity follows Clausius–Clapeyron scaling, considerably greater than the typical 2%–3% K⁻¹over oceans. Over fixed saturated surfaces, the theory reconciles divergent explanations for hydrological sensitivity based on surface and atmospheric energy budgets, with changes in near-surface relative humidity playing a key role. Finally, the theory shows that PET primarily scales with surface net radiation, rather than temperature or vapor pressure deficit, in agreement with recent empirical findings. The predicted PET scaling implies only modest changes in global mean aridity with warming, rather than the large increases implied by some prior studies. Biological plant responses to increasing carbon dioxide (CO₂) are not essential to this explanation. Significance StatementWill global warming make the world more arid? There has been a lot of debate on this question, with some arguing it will drastically increase aridity. Answering it requires understanding changes in atmospheric water demand: the evapotranspiration that would occur if the land surface was always kept saturated. We use basic physics to understand climate over land surfaces in which soils are kept saturated—and, more broadly, fixed at any level of saturation, from wet to dry. Our results support the view that global warming will not drastically increase aridity, on average. We also show that rainfall increases with warming at a faster rate over fixed dry land surfaces than it does on Earth (where land surfaces change from dry to wet and back again). 

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