Heat-flux-limited Cloud Activity and Vertical Mixing in Giant Planet Atmospheres with an Application to Uranus and Neptune

IF 3.8 Q2 ASTRONOMY & ASTROPHYSICS The Planetary Science Journal Pub Date : 2024-04-22 DOI:10.3847/psj/ad0ed3
Huazhi Ge, 华志 葛, Cheng Li, Xi Zhang and Chris Moeckel
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Abstract

Storms operated by moist convection and the condensation of CH4 or H2S 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 CH4 and H2S 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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巨行星大气中的热通量限制云活动和垂直混合,以及天王星和海王星的应用
在天王星和海王星上观测到了由潮湿对流和 CH4 或 H2S 冷凝产生的风暴。然而,冰巨行星气象层的云形成机制、热结构和混合效率仍不清楚。本文表明,在巨行星上,尤其是在行星热通量较弱的冰巨星上,湿对流受到热传输的限制。与凝结和蒸发相关的潜热可以通过降水有效地将热量带过天气层。在没有完整水文循环的以往研究中,这种效应通常被忽视。我们首先推导出分析理论,并证明云密度的上限由行星热通量和云的微物理决定,但与大气成分无关。水汽的涡度扩散取决于行星热通量、大气成分和地表重力,但与云的微物理学没有直接关系。然后,我们利用 SNAP 进行对流和云解析模拟,以验证我们的分析理论。模拟的云密度和涡度扩散率比平衡云凝结模型和混合长度理论得出的结果小几个数量级,但与我们的分析解一致。同时,CH4 和 H2S 的质量负荷效应导致了超绝热和稳定的天气层。我们模拟产生的三个云层与最近的观测结果在性质上非常相似。这项研究对一般巨行星大气中云层的形成和涡流混合以及未来太空任务和地面望远镜的观测具有重要意义。
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来源期刊
The Planetary Science Journal
The Planetary Science Journal Earth and Planetary Sciences-Geophysics
CiteScore
5.20
自引率
0.00%
发文量
249
审稿时长
15 weeks
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