Origin of multiple Lifshitz transitions in the Weyl semi-metal RhSi

Abstract

It is known from density functional theory (DFT) calculations that RhSi has a multifold degenerate Dirac point at the Fermi energy, with the dominant states in the low-energy region displaying mostly Rh d character. Using DFT+U, we calculate the band structure by considering an effective local interaction on the Rh d states, with a realistic effective Hubbard Ueff=2.5 eV derived from a constrained random-phase approximation calculation, and find the emergence of a double hump structure close to the Fermi energy.By further deriving a low-energy tight-binding model from our first-principles results, we show that the double hump is a direct consequence of a competition between the Rh d-Rh d and Rh d-Si p interactions, which differ in their momentum dependence. As a consequence, through an artificial tuning of the energy level of the Si p orbitals this hump structure can be suppressed due to the effectively reduced Rh d -Si p interaction.This peculiar low-energy electronic structure additionally results in that a small hole/electron doping ( 0.1 \%) can tune the Fermi surface topology, going from closed to open Fermi surfaces, which has dramatic consequences for the thermal transport.