The effect of spectral resolution on biosignature detection via reflected light observations of the Earth through time

Abstract

NASA's Habitable Worlds Observatory (HWO) will search for biosignatures on Earth-like exoplanets using reflected light spectroscopy. A critical instrument design parameter is resolving power, which must balance biosignature detectability against exposure time and detector noise constraints. We assess the resolving power needed to detect and characterize key biosignature gases and habitability indicators including O2, O3, H2O, CH4, CO2 and CO across atmospheres representing the Archean, Proterozoic, and Phanerozoic Earth. We combine analytical detectability calculations spanning spectral resolutions (λ/λ) R=20-5000 with atmospheric retrievals using the rfast radiative transfer model and pyEDITH exposure time calculator for realistic wavelength-dependent noise modeling. In the visible (0.4-1.0 μm), the nominal resolution RVis=140 is sufficient for detecting O2 in Phanerozoic-like atmospheres. Higher resolutions could theoretically reduce exposure times for low-O2 Proterozoic atmospheres, but require >10× reductions in dark current and could increase H2O detection exposure times by 2×, penalizing the foundational habitability constraint that anchors downstream biosignature searches. The most efficient path for low-O2 atmospheres may instead be indirect inference via O3, whose Hartley-Huggins bands are detectable at RUV 7. In the near-IR (1.0-1.7 μm), RNIR≥40 is necessary to avoid a degeneracy between CO2 and CO that could produce false positive detections of abundant CO. The nominal RNIR=70 is sufficient for characterizing all Earth-through-time cases. These results support HWO's current baseline resolution choices and provide actionable guidance for finalizing spectrometer requirements while maintaining technological feasibility for the search for life on exoplanets.