PrBi: Topology meets quadrupolar degrees of freedom

Abstract

Novel materials incorporating electronic degrees of freedom other than charge, including spin, orbital or valley et al have manifested themselves to be of the great interests and applicable potentials. Recently, the multipolar degrees of freedom have attracted remarkable attention in the electronic correlated effects. In this work, we systematically studied the transport, magnetic and thermodynamic properties of the topological semimetal candidate PrBi in the framework of crystalline electric field theory. Our results demonstrate the 3 non-Kramers doublet as the ground state of Pr3+ (4f2) ions. This ground state is nonmagnetic but carries a non-zero quadrupolar moment O20. A quadrupolar phase transition is inferred below 0.08 K. No obvious quadrupolar Kondo effect can be identified. Ultrahigh-field quantum oscillation measurements confirm PrBi as a semimetal with non-trivial Berry phase and low total carrier density 0.06 /f.u. We discuss the interplay between low carrier density and 4f2 quadrupolar moment, and ascribe the weak quadrupolar ordering and Kondo effect to consequences of the low carrier density. PrBi, thus, opens a new window to the physics of topology and strongly correlated effect with quadrupolar degrees of freedom in the low-carrier-density limit, evoking the need for a reexamination of the Nozi\`eres exhaustion problem in the context of multi-channel Kondo effect.