# Assessing the Habitability of the TRAPPIST-1 System Using a 3D Climate   Model

**Authors:** Eric T. Wolf

arXiv: 1703.05815 · 2018-04-03

## TL;DR

This study uses a 3D climate model to evaluate the habitability of TRAPPIST-1 planets, finding that only planet e may currently support habitable conditions with suitable atmospheric compositions.

## Contribution

It applies a 3D climate model to assess habitability of TRAPPIST-1 planets considering realistic atmospheric and orbital parameters, identifying planet e as the most promising candidate.

## Key findings

- Inner planets are likely dry due to past runaway greenhouse effects.
- Outer planets are too cold, entering snowball states despite high CO2 atmospheres.
- Planet e could sustain habitable conditions with specific atmospheric compositions.

## Abstract

The TRAPPIST-1 system provides an extraordinary opportunity to study multiple terrestrial extrasolar planets and their atmospheres. Here we use the National Center for Atmospheric Research Community Atmosphere Model version 4 to study the possible climate and habitability of the planets in the TRAPPIST-1 system. We assume ocean-covered worlds, with atmospheres comprised of N2, CO2, and H2O, and with orbital and geophysical properties defined from observation. Model results indicate that the inner three planets (b, c, and d) presently reside interior to the inner edge of the traditional liquid water habitable zone. Thus if water ever existed on the inner planets, they would have undergone a runaway greenhouse and lost their water to space, leaving them dry today. Conversely the outer 3 planets (f, g, and h) fall beyond the maximum CO2 greenhouse outer edge of the habitable zone. Model results indicate that the outer planets cannot be warmed despite as much as 30 bar CO2 atmospheres, instead entering a snowball state. The middle planet (e) represents the best chance for a presently habitable ocean-covered world in the TRAPPIST-1 system. Planet e can maintain at least some habitable surface area with 0 - 2 bar CO2, depending on the background N2 content. Near present day Earth surface temperatures can be maintained for an ocean-covered planet e with either 1 bar N2 and 0.4 bar CO2, or a 1.3 bar pure CO2 atmosphere.

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Source: https://tomesphere.com/paper/1703.05815