# A Volcanic Hydrogen Habitable Zone

**Authors:** Ramses Ramirez, Lisa Kaltenegger

arXiv: 1702.08618 · 2017-03-01

## TL;DR

This paper proposes that volcanic outgassing of hydrogen can significantly extend the habitable zone around stars beyond traditional limits, especially for planets with substantial volcanic hydrogen atmospheres, enhancing potential habitability.

## Contribution

It introduces the concept of a volcanic hydrogen habitable zone, extending the classical habitable zone by incorporating volcanic H2 outgassing effects into climate models.

## Key findings

- Hydrogen outgassing can extend the habitable zone to ~2.4 AU in our Solar System.
- The outer edge of the habitable zone can be shifted outward by 30-60% with high hydrogen concentrations.
- Atmospheric scale heights increase, aiding remote detection of volcanic hydrogen atmospheres.

## Abstract

The classical habitable zone is the circular region around a star in which liquid water could exist on the surface of a rocky planet. The outer edge of the traditional N2-CO2-H2O habitable zone (HZ) extends out to nearly 1.7 AU in our Solar System, beyond which condensation and scattering by CO2 outstrips its greenhouse capacity. Here, we show that volcanic outgassing of atmospheric H2 on a planet near the outer edge can extend the habitable zone out to ~2.4 AU in our solar system. This wider volcanic hydrogen habitable zone (N2-CO2-H2O-H2) can be sustained as long as volcanic H2 output offsets its escape from the top of the atmosphere. We use a single-column radiative-convective climate model to compute the HZ limits of this volcanic hydrogen habitable zone for hydrogen concentrations between 1% and 50%, assuming diffusion-limited atmospheric escape. At a hydrogen concentration of 50%, the effective stellar flux required to support the outer edge decreases by ~35% to 60% for M to A stars. The corresponding orbital distances increase by ~30% to 60%. The inner edge of this HZ only moves out by ~0.1 to 4% relative to the classical HZ because H2 warming is reduced in dense H2O atmospheres. The atmospheric scale heights of such volcanic H2 atmospheres near the outer edge of the HZ also increase, facilitating remote detection of atmospheric signatures.

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Source: https://tomesphere.com/paper/1702.08618