Carbonate-silicate cycle predictions of Earth-like planetary climates and testing the habitable zone concept
Owen Lehmer, David C. Catling, Joshua Krissansen‐Totton
Abstract
Abstract In the conventional habitable zone (HZ) concept, a CO 2 -H 2 O greenhouse maintains surface liquid water. Through the water-mediated carbonate-silicate weathering cycle, atmospheric CO 2 partial pressure (pCO 2 ) responds to changes in surface temperature, stabilizing the climate over geologic timescales. We show that this weathering feedback ought to produce a log-linear relationship between pCO 2 and incident flux on Earth-like planets in the HZ. However, this trend has scatter because geophysical and physicochemical parameters can vary, such as land area for weathering and CO 2 outgassing fluxes. Using a coupled climate and carbonate-silicate weathering model, we quantify the likely scatter in pCO 2 with orbital distance throughout the HZ. From this dispersion, we predict a two-dimensional relationship between incident flux and pCO 2 in the HZ and show that it could be detected from at least 83 (2 σ ) Earth-like exoplanet observations. If fewer Earth-like exoplanets are observed, testing the HZ hypothesis from this relationship could be difficult.