The Hycean Paradigm in the Search for Life Elsewhere

TL;DR

This paper discusses the Hycean paradigm, a new class of habitable exoplanets with thick hydrogen atmospheres and oceans, and reports the first detection of methane and carbon dioxide in such a planet using JWST, advancing the search for extraterrestrial life.

Contribution

It introduces the Hycean world concept and presents the first atmospheric detection of key molecules on a candidate Hycean planet, demonstrating their observational accessibility.

Findings

Detection of methane (CH4) and carbon dioxide (CO2) in K2-18 b's atmosphere.

Evidence supporting the potential habitability of Hycean worlds.

Implications for future atmospheric observations with JWST.

Abstract

The search for habitable conditions and signs of life on exoplanets is a major frontier in modern astronomy. Detecting atmospheric signatures of Earth-like exoplanets is challenging due to their small sizes and relatively thin atmospheres. Recently, a new class of habitable sub-Neptune exoplanets, called Hycean worlds, has been theorized. Hycean worlds are planets with H2-rich atmospheres and planet-wide oceans with thermodynamic conditions similar to those in the Earth's oceans. Their large sizes and extended atmospheres, compared to rocky planets of similar mass, make Hycean worlds significantly more accessible to atmospheric observations. These planets open a new avenue in the search for planetary habitability and life elsewhere using spectroscopic observations with the James Webb Space Telescope (JWST). We observed the transmission spectrum of a candidate Hycean world, K2-18 b, recently with JWST in its first year of operations. The spectrum reveals multiple spectral features of carbon bearing molecules in the planetary atmosphere, leading to the first detections of methane (CH4) and carbon dioxide (CO2) in a habitable-zone exoplanet. We discuss inferences of the atmospheric chemical composition and its implications for the atmospheric, interior and surface conditions on the planet, along with the possibility of a habitable ocean underneath the atmosphere. We discuss new observational and theoretical developments in this emerging frontier and their implications for exoplanetary habitability and search for life elsewhere.