On the limitations of Hα luminosity as a star formation tracer in spatially resolved observations

This study examines the limitations of H luminosity as a tracer of star formation rates (SFR) in spatially resolved observations. We carry out high-resolution simulations of a Milky Way-like galaxy including both supernova and photoionization feedback, and from these, we generate synthetic H emission maps that we compare to maps of the true distribution of young stellar objects (YSOs) on scales from whole-galaxy to individual molecular clouds (pc). Our results reveal significant spatial mismatches between H and true YSO maps on sub-100 pc scales, primarily due to ionizing photon leakage, with a secondary contribution from young stars drifting away from their parent molecular clouds. On small scales, these effects contribute significantly to the observed anticorrelation between gas and star formation, such that there is less anticorrelation if we replace an H-based star formation map with a YSO-based one; this in turn implies that previous studies have underestimated the time it takes for young stars to disperse their parent molecular clouds. However, these effects are limited in dense regions with hydrogen columns cm, where the H- and YSO-based SFR maps show better agreement. Based on this finding, we propose a calibration model that can precisely measure the SFR of large molecular clouds (mean radius > 100 pc) with a combination of H and CO observations, which provides a foundation for future study of star formation processes in extragalactic molecular clouds.