Logarithmic corrections to near-extremal entropy of charged de Sitter black holes

Abstract: We calculate the logarithmic temperature corrections to the thermodynamic entropy of four-dimensional near-extremal Reissner-Nordstr\"{o}m de Sitter (dS) black hole by computing a one-loop contribution within the path integral framework in the near-horizon limit. Due to the presence of three horizons, the extremal limit of a charged dS black hole is uniquely intriguing and remarkably different from its flat and AdS counterparts. In the near-horizon limit, there are three distinct extremal limits known as cold, Nariai, and ultracold configurations, each corresponding to a different product geometry structure involving AdS$_2$, dS$_2$ and Mink$_2$ respectively, where all of them contain a $S^2$. We compute the tensor zero modes of the Lichnerowicz operator acting on linearized metric perturbations for the cold and Nariai extremal limits which are associated with near-horizon AdS$_2$ and dS$_2$ asymptotic symmetries. While the path integral over these zero modes results in an infrared divergence within the one-loop approximation to the partition function, we regulate the divergence by introducing a small, finite temperature perturbative correction to the extremal geometry.