Storms and convection on Uranus and Neptune: impact of methane abundance revealed by a 3D cloud-resolving model

Noé Clément, Jérémy Leconte, Aymeric Spiga, Sandrine Guerlet, Franck Selsis, Gwenaël Milcareck, Lucas Teinturier, Thibault Cavalié, Raphaël Moreno, Emmanuel Lellouch, Óscar Carrión-González
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Abstract

Uranus and Neptune have atmospheres dominated by molecular hydrogen and helium. In the upper troposphere, methane is the third main molecule and condenses, yielding a vertical gradient in CH4. This condensable species being heavier than H2 and He, the resulting change in mean molecular weight due to condensation comes as a factor countering dry and moist convection. As observations also show latitudinal variations in methane abundance, one can expect different vertical gradients from one latitude to another. In this paper, we investigate the impact of this methane vertical gradient on the atmospheric regimes, especially on the formation and inhibition of moist convective storms in the troposphere of ice giants. We develop a 3D cloud-resolving model to simulate convective processes. Using our simulations, we conclude that typical velocities of dry convection in the deep atmosphere are rather low (of the order of 1 m/s) but sufficient to sustain upward methane transport, and that moist convection at methane condensation level is strongly inhibited. Previous studies derived an analytical criterion on the methane vapor amount above which moist convection should be inhibited. We first validate this analytical criterion numerically. We then show that the critical methane abundance governs the inhibition and formation of moist convective storms, and we conclude that the intensity and intermittency of these storms should depend on the methane abundance and saturation. In ice giants, dry convection is weak, and moist convection is strongly inhibited. However, when enough methane is transported upwards, through dry convection and turbulent diffusion, sporadic moist convective storms can form. These storms should be more frequent on Neptune than on Uranus, because of Neptune's internal heat flow. Our results can explain the observed sporadicity of clouds in ice giants.
天王星和海王星上的风暴和对流:三维云解析模型揭示的甲烷丰度的影响
天王星和海王星的大气层以分子氢和氦为主。在对流层上部,甲烷是第三种主要分子并发生冷凝,从而产生 CH4 的垂直梯度。这种可凝结的物质比氢和氦重,凝结导致的平均分子量的变化是对抗干湿对流的一个因素。由于观测结果也显示出甲烷丰度的纬度变化,因此可以预计不同纬度的垂直梯度也不同。在本文中,我们研究了这种甲烷垂直梯度对对流层状态的影响,特别是对冰巨行星对流层湿对流风暴的形成和抑制的影响。我们建立了一个三维云解析模型来模拟对流过程。通过模拟,我们得出结论:大气深处干对流的典型速度相当低(大约 1 米/秒),但足以维持向上的甲烷传输,而甲烷凝结层的湿对流则受到强烈抑制。以前的研究得出了一个甲烷蒸汽量的分析标准,超过这个标准,潮湿对流就会受到抑制。我们首先对这一分析标准进行了数值验证。我们的结论是,这些风暴的强度和间歇性应取决于甲烷丰度和饱和度。在冰巨行星中,干对流很弱,湿对流受到强烈抑制。然而,当有足够的甲烷通过干对流和湍流扩散向上输送时,就会形成零星的湿对流风暴。由于海王星的内部热流,这些风暴在海王星上应该比在天王星上更为频繁。我们的结果可以解释在冰巨星上观测到的云的零星性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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