Huazhi 华志 Ge 葛's scientific contributions

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Publications (1)

Figure 1. Conceptual art about cloud formation and moist convection in the atmosphere of different planets. Panel (a) shows that solar radiation is the driving force and the energy source of cloud formation in Earth's atmosphere. On the other hand, panel (b) shows that the planetary heat flux is the driving force of cloud formation on giant planets since solar radiation stabilizes the atmosphere and against convection. Note that the concept in (b) is also applicable to free-floating substellar bodies like field brown dwarfs but not applicable to strongly irradiated giant planets like hot or warm Jupiter. Cloud morphology in this art does not necessarily represent the real ones.
Heat-flux-limited Cloud Activity and Vertical Mixing in Giant Planet Atmospheres with an Application to Uranus and Neptune
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April 2024

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30 Reads

The Planetary Science Journal

Huazhi 华志 Ge 葛

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Cheng Li

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Xi Zhang

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Chris Moeckel

Storms operated by moist convection and the condensation of CH 4 or H 2 S have been observed on Uranus and Neptune. However, the mechanism of cloud formation, thermal structure, and mixing efficiency of ice giant weather layers remains unclear. In this paper, we show that moist convection is limited by heat transport on giant planets, especially on ice giants where planetary heat flux is weak. Latent heat associated with condensation and evaporation can efficiently bring heat across the weather layer through precipitations. This effect was usually neglected in previous studies without a complete hydrological cycle. We first derive analytical theories and show that the upper limit of cloud density is determined by the planetary heat flux and microphysics of clouds but is independent of the atmospheric composition. The eddy diffusivity of moisture depends on the planetary heat fluxes, atmospheric composition, and surface gravity but is not directly related to cloud microphysics. We then conduct convection- and cloud-resolving simulations with SNAP to validate our analytical theory. The simulated cloud density and eddy diffusivity are smaller than the results acquired from the equilibrium cloud condensation model and mixing length theory by several orders of magnitude but consistent with our analytical solutions. Meanwhile, the mass-loading effect of CH 4 and H 2 S leads to superadiabatic and stable weather layers. Our simulations produced three cloud layers that are qualitatively similar to recent observations. This study has important implications for cloud formation and eddy mixing in giant planet atmospheres in general and observations for future space missions and ground-based telescopes.

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