Highly asymmetric superconducting dome and strange metallicity in La3Ni2O7

Abstract

The recent discovery of high-temperature superconductivity in La3Ni2O7 under high pressure has stimulated intensive investigations concerning its paring mechanism and a correct description of its effective low-energy physics. Notable experimental observations include the right-triangle-shaped superconducting dome with the maximum Tc of about 80 K and the strange metal behavior in the normal state above Tc. Here we apply the Schwinger boson approach to the bilayer t-V-J model, which allows us to treat well both the magnetic correlations and the superconducting instability. We obtain a global phase diagram with both metallic and superconducting ground states separated by a quantum phase transition, and predict a minimal interlayer superexchange J and a minimal dz2-hole concentration necessary for the superconductivity, with a highly asymmetric right-triangle-like shape for the Tc curve as well as a maximum Tc comparable with experiments. The normal state is featured with a pseudogap in the dx2-y2 spectra associated with preformed Cooper pairs and non-Fermi liquid strange metal behavior due to hybridization-induced spinon-holon-electron scattering. Our work clarifies the key difference of the two-component scenario of the superconductivity from other mechanisms, and provides a consistent understanding of the high-temperature superconductivity and strange metallic properties of La3Ni2O7 under high pressure.