Hydrostatic Pressure-Induced Evolution of the Superconducting Transition Temperature of Bi-2212: Insights from First-Principles Calculations

Abstract

High-pressure experiments on Bi2Sr2CaCu2O8+x (Bi-2212) have reported apparently conflicting evolutions of the superconducting transition temperature Tc, ranging from weak enhancement to strong suppression and even a proposed second superconducting dome. To clarify the origin of these discrepancies, we combine first-principles density functional theory calculations with a pressure-dependent low-energy bilayer model solved by the slave-boson mean-field method together with a Berezinskii-Kosterlitz-Thouless estimate of phase coherence. Our results show that hydrostatic pressure induces a pronounced self-doping effect in Bi-2212: holes are transferred from the Bi-O charge-reservoir layers to the CuO2 superconducting planes, leading to a systematic increase in the effective CuO2-plane hole concentration δx. At the same time, pressure enhances the pairing scale through the renormalization of the hopping and superexchange parameters. As a consequence, the pressure evolution of Tc is governed by the competition between pressure-enhanced pairing and pressure-driven motion along the common Tc-δx dome, making Tc(P) highly sensitive to the initial doping state. Even samples with very similar ambient-pressure Tc but slightly different initial doping can therefore display qualitatively different pressure responses. This provides a unified interpretation of a large part of the disparate high-pressure behavior reported for Bi-2212 and suggests that slightly underdoped samples are more favorable than ambient-pressure optimal samples for achieving improved superconducting performance under pressure.