Doping evolution of the normal state magnetic excitations in pressurized La3Ni2O7

TL;DR

This study theoretically examines how magnetic excitations in pressurized La3Ni2O7 evolve with doping, revealing robust features and a Lifshitz transition that may influence superconductivity mechanisms.

Contribution

It provides a detailed theoretical analysis of magnetic excitations and their doping dependence in La3Ni2O7, highlighting features not previously identified.

Findings

Magnetic excitations show a square-like pattern at n=3.0

Strong modulation of excitations with interlayer momentum qz

Lifshitz transition occurs in heavily electron-doped regime

Abstract

The doping evolution behaviors of the normal state magnetic excitations (MEs) of the nickelate La3Ni2O7 are theoretically studied in this paper. For a filling of n = 3.0 which corresponds roughly to the material which realizes the superconductivity of about 80 K under moderately high pressures above 14 GPa, the MEs exhibit a square-like pattern centered at (0,0) which originates from the intrapocket particle-hole scatterings. Furthermore, it was found that the MEs show very strong modulations on the interlayer momentum qz. With the increasing of qz, the patterns of the MEs change dramatically. In the large qz regime, they turn to be ruled by the interpocket excitation modes with significantly larger intensity which may play a vital role in the superconducting pairing. This hidden feature of the MEs was not revealed by previous studies. The established features of the MEs are found to be very robust against doping. They persist in the wide hole- or electron-doping regime around n = 3.0. However, in the heavily electron-doped regime, a Lifshitz transition will occur. Consequently, the behaviors of the MEs change qualitatively across this transition. With the absence of the hole pocket, we predict that a strong tendency toward the spin-density-wave (SDW) order will develop due to the perfect nesting between the electron and the hole pockets at n = 4.0. Thus, we have investigated the normal state behaviors of the MEs and their doping evolutions which may shed light on the mechanism of superconductivity in pressurized La3Ni2O7.