Pressure Driven Fractionalization of Ionic Spins Results in Cupratelike High-Tc Superconductivity in La3Ni2O7

Abstract

Beyond 14GPa of pressure, bi-layered La3Ni2O7 was recently found to develop strong superconductivity above the liquid nitrogen boiling temperature. An immediate essential question is the pressure-induced qualitative change of electronic structure that enables the exciting high-temperature superconductivity. We investigate this timely question via a numerical multi-scale derivation of effective many-body physics. At the atomic scale, we first clarify that the system has a strong charge transfer nature with itinerant carriers residing mainly in the in-plane oxygen between spin-1 Ni2+ ions. We then elucidate in eV- and sub-eV-scale the key physical effect of the applied pressure: It induces a cupratelike electronic structure through partially screening the Ni spin from 1 to 1/2. This suggests a high-temperature superconductivity in La3Ni2O7 with microscopic mechanism and (d-wave) symmetry similar to that in the cuprates.