📝 SummarXiv

Abstract

Scalar-tensor gravity represents a natural extension of general relativity. Testing such models experimentally provides a crucial pathway to probing physics at high-energy scales, particularly in the context of string theory. This paper investigates a string-theory-inspired scalar-tensor gravity -- the dilaton model -- and identifies regions of its parameter space potentially constrained by gravitational redshift experiments in future. By further modeling the mass distribution in low-density environments with a discrete representation, we go beyond the standard continuous approximation. Despite limitations inherent to specific experimental configurations, our analysis reveals that a significant portion of the parameter space remains accessible. Consequently, high-precision gravitational redshift experiments hold the potential to exclude significant regions of this parameter space in future.