Temperature Dependence of the Momentum-Resolved Static Spin Susceptibility in a Mott-Proximate Cuprate Model

Abstract

This paper presents the temperature dependence of the static spin susceptibility at q = (π, π) and q = (π, 0) in a Mott-proximate cuprate model with an s-wave like pseudogap -- a model system for high-temperature superconducting (HTSC) cuprates. The results show the susceptibility onset temperature tracks the critical temperature (Tc) of HTSCs with a comparable scale across the electron filling factor. Also, as the electron filling decreases and the chemical potential approaches the antinodal van Hove region, the susceptibility at q=(π,0) -- the axial particle-hole response -- grows markedly. It suggests that the emergence of cuprate superconductivity correlates with a suppression of low-energy antinodal spin response and associated particle-hole excitations, which would otherwise dephase d-wave pairing, commonly attributed to spin fluctuations. In this context, the pseudogap partially suppresses antinodal spectral weight near ω= 0, thereby reducing the low-ω particle-hole phase space.