# Quantitative estimates of the surface habitability of Kepler-452b

**Authors:** Laura Silva (1), Giovanni Vladilo (1), Giuseppe Murante (1), Antonello, Provenzale (2), ((1) INAF-OATs, Trieste, Italy, (2) IGG-CNR, Pisa, Italy)

arXiv: 1706.01224 · 2017-07-26

## TL;DR

This study models the surface habitability of Kepler-452b, considering various climate factors, and identifies conditions under which the planet could sustain biosignature-producing activity for billions of years.

## Contribution

It introduces a temperature-dependent habitability index for Kepler-452b and explores how different planetary parameters influence its potential habitability.

## Key findings

- Habitability is maximized at low CO₂ partial pressures.
- High orbital eccentricity reduces habitability.
- Long-term habitability is possible under specific parameter combinations.

## Abstract

Kepler-452b is currently the best example of an Earth-size planet in the habitable zone of a sun-like star, a type of planet whose number of detections is expected to increase in the future. Searching for biosignatures in the supposedly thin atmospheres of these planets is a challenging goal that requires a careful selection of the targets. Under the assumption of a rocky-dominated nature for Kepler-452b, we considered it as a test case to calculate a temperature-dependent habitability index, $h_{050}$, designed to maximize the potential presence of biosignature-producing activity (Silva et al.\ 2016). The surface temperature has been computed for a broad range of climate factors using a climate model designed for terrestrial-type exoplanets (Vladilo et al.\ 2015). After fixing the planetary data according to the experimental results (Jenkins et al.\ 2015), we changed the surface gravity, CO$_2$ abundance, surface pressure, orbital eccentricity, rotation period, axis obliquity and ocean fraction within the range of validity of our model. For most choices of parameters we find habitable solutions with $h_{050}>0.2$ only for CO$_2$ partial pressure $p_\mathrm{CO_2} \lesssim 0.04$\,bar. At this limiting value of CO$_2$ abundance the planet is still habitable if the total pressure is $p \lesssim 2$\,bar. In all cases the habitability drops for eccentricity $e \gtrsim 0.3$. Changes of rotation period and obliquity affect the habitability through their impact on the equator-pole temperature difference rather than on the mean global temperature. We calculated the variation of $h_{050}$ resulting from the luminosity evolution of the host star for a wide range of input parameters. Only a small combination of parameters yield habitability-weighted lifetimes $\gtrsim 2$\,Gyr, sufficiently long to develop atmospheric biosignatures still detectable at the present time.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1706.01224/full.md

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1706.01224/full.md

## References

55 references — full list in the complete paper: https://tomesphere.com/paper/1706.01224/full.md

---
Source: https://tomesphere.com/paper/1706.01224