# Theoretical Reflectance Spectra of Earth-Like Planets through Their   Evolutions: Impact of Clouds on the Detectability of Oxygen, Water, and   Methane with Future Direct Imaging Missions

**Authors:** Yui Kawashima, Sarah Rugheimer

arXiv: 1904.01019 · 2019-05-15

## TL;DR

This study models how clouds affect the spectral detection of key molecules like oxygen, water, and methane on Earth-like planets, informing future telescope observations and their feasibility.

## Contribution

It provides a detailed analysis of cloud effects on molecular detectability across different planetary epochs for upcoming direct imaging missions.

## Key findings

- Oxygen detection time varies with cloud properties and atmospheric composition.
- Lower altitude clouds and higher oxygen levels reduce detection time.
- Detection of oxygen is feasible within 10 hours for certain cloud conditions with LUVOIR.

## Abstract

In the near-future, atmospheric characterization of Earth-like planets in the habitable zone will become possible via reflectance spectroscopy with future telescopes such as the proposed LUVOIR and HabEx missions. While previous studies have considered the effect of clouds on the reflectance spectra of Earth-like planets, the molecular detectability considering a wide range of cloud properties has not been previously explored in detail. In this study, we explore the effect of cloud altitude and coverage on the reflectance spectra of Earth-like planets at different geological epochs and examine the detectability of $\mathrm{O_2}$, $\mathrm{H_2O}$, and $\mathrm{CH_4}$ with test parameters for the future mission concept, LUVOIR, using a coronagraph noise simulator previously designed for WFIRST-AFTA. Considering an Earth-like planet located at 5 pc away, we have found that for the proposed LUVOIR telescope, the detection of the $\mathrm{O_2}$ A-band feature (0.76 $\mathrm{\mu}$m) will take approximately 100, 30, and 10 hours for the majority of the cloud parameter space modeled for the atmospheres with 10\%, 50\%, and 100\% of modern Earth O$_2$ abundances, respectively. Especially, for {the case of $\gtrsim 50$\%} of modern Earth O$_2$ abundance, the feature will be detectable with integration time $\lesssim 10$ hours as long as there are lower altitude ($\lesssim 8$ km) clouds with a global coverage of $\gtrsim 20\%$. For the 1\% of modern Earth $\mathrm{O_2}$ abundance case, however, it will take more than 100 hours for all the cloud parameters we modeled.

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1904.01019/full.md

## References

78 references — full list in the complete paper: https://tomesphere.com/paper/1904.01019/full.md

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Source: https://tomesphere.com/paper/1904.01019