The Hydrostatic Mass Bias and the σ8 Tension: A Multi-Probe Forecast for Stage-IV/V Surveys

Abstract

The hydrostatic mass bias (bHSE) is a leading systematic uncertainty in cluster cosmology and a principal source of degeneracy with σ8 and Ωm. We investigate the capability of Stage-IV CMB and optical surveys to calibrate bHSE using tomographic cross-correlations between the thermal Sunyaev--Zel'dovich (tSZ) effect, galaxy clustering, and weak lensing. We perform a Fisher forecast incorporating realistic survey noise, foreground modeling for clustered CIB and radio sources, and full marginalization over cosmological and astrophysical nuisance parameters, including per-bin galaxy bias perturbations, photometric redshift shifts, intrinsic alignments, and baryonic feedback modeled with HMCode2020. With optimized tomographic binning (10 lens and 5 source bins for LSST; 6 lens and 5 source bins for CSST), we forecast marginalized constraints of 0.98\% for SO+LSST, 1.60\% for CMB-S4+LSST, and 2.40\% for CMB-S4+CSST. Tomography improves bHSE precision by factors of approximately three relative to non-tomographic analyses, reflecting the role of redshift information in breaking the bHSE--σ8 degeneracy. Optical-only probes provide no direct constraint on bHSE, whereas inclusion of tSZ-containing spectra enables percent-level calibration under realistic systematic assumptions. The results demonstrate that multi-probe tomographic analyses with Stage-IV surveys can achieve robust control of hydrostatic mass bias, strengthening cluster-based constraints on structure growth.