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Main Authors: Zhong, Wei, Zhang, Zhen-Tai, Zhong, Hui-Sheng, Ma, Bo, Tan, Xianyu, Yu, Cong
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.12605
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author Zhong, Wei
Zhang, Zhen-Tai
Zhong, Hui-Sheng
Ma, Bo
Tan, Xianyu
Yu, Cong
author_facet Zhong, Wei
Zhang, Zhen-Tai
Zhong, Hui-Sheng
Ma, Bo
Tan, Xianyu
Yu, Cong
contents Observations have revealed unique temperature profiles in hot Jupiter atmospheres. We propose that the energy transport by vertical mixing could lead to such thermal features. In our new scenario, strong absorbers, TiO and VO are not necessary. Vertical mixing could be naturally excited by atmospheric circulation or internal gravity wave breaking. We perform radiative transfer calculations by taking into account the vertical mixing driven energy transport. The radiative equilibrium (RE) is replaced by radiative-mixing equilibrium (RME). We investigate how the mixing strength, $K_{\rm zz}$, affects the atmospheric temperature-pressure profile. Strong mixing can heat the lower atmosphere and cool the upper atmosphere. This effect has important effects on the atmosphere thermal features that would form without mixing. In certain circumstances, it can induce temperature inversions in scenarios where the temperature monotonically increases with increasing pressure under conditions of lower thermal band opacity. Temperature inversions show up as $K_{\rm zz}$ increases with altitude due to shear interaction with the convection layer. The atmospheric thermal structure of HD~209458b can be well fitted with $K_{\rm zz} \propto (P/1\ {\rm bar})^{-1/2}\ {\rm cm}^{2} \ {\rm s}^{-1}$. Our findings suggest vertical mixing promotes temperature inversions and lowers $K_{\rm zz}$ estimates compared to prior studies. Incorporating chemical species into vertical mixing will significantly affect the thermal profile due to their temperature sensitivity.
format Preprint
id arxiv_https___arxiv_org_abs_2411_12605
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Irradiated Atmospheres I: Heating by Vertical-Mixing Induced Energy Transport
Zhong, Wei
Zhang, Zhen-Tai
Zhong, Hui-Sheng
Ma, Bo
Tan, Xianyu
Yu, Cong
Earth and Planetary Astrophysics
Observations have revealed unique temperature profiles in hot Jupiter atmospheres. We propose that the energy transport by vertical mixing could lead to such thermal features. In our new scenario, strong absorbers, TiO and VO are not necessary. Vertical mixing could be naturally excited by atmospheric circulation or internal gravity wave breaking. We perform radiative transfer calculations by taking into account the vertical mixing driven energy transport. The radiative equilibrium (RE) is replaced by radiative-mixing equilibrium (RME). We investigate how the mixing strength, $K_{\rm zz}$, affects the atmospheric temperature-pressure profile. Strong mixing can heat the lower atmosphere and cool the upper atmosphere. This effect has important effects on the atmosphere thermal features that would form without mixing. In certain circumstances, it can induce temperature inversions in scenarios where the temperature monotonically increases with increasing pressure under conditions of lower thermal band opacity. Temperature inversions show up as $K_{\rm zz}$ increases with altitude due to shear interaction with the convection layer. The atmospheric thermal structure of HD~209458b can be well fitted with $K_{\rm zz} \propto (P/1\ {\rm bar})^{-1/2}\ {\rm cm}^{2} \ {\rm s}^{-1}$. Our findings suggest vertical mixing promotes temperature inversions and lowers $K_{\rm zz}$ estimates compared to prior studies. Incorporating chemical species into vertical mixing will significantly affect the thermal profile due to their temperature sensitivity.
title Irradiated Atmospheres I: Heating by Vertical-Mixing Induced Energy Transport
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2411.12605