Enhanced hybridization sets the stage for electronic nematicity in CeRhIn5

Abstract

High magnetic fields induce a pronounced in-plane electronic anisotropy in the tetragonal antiferromagnetic metal CeRhIn5 at H* 30 T for fields 20o off the c-axis. Here we investigate the response of the underlying crystal lattice in magnetic fields to 45 T via high-resolution dilatometry. Within the antiferromagnetic phase of CeRhIn5, a finite magnetic field component in the tetragonal ab-plane explicitly breaks the tetragonal (C4) symmetry of the lattice well below H* revealing a finite nematic susceptibility at low fields. A modest magnetostriction anomaly, dL/L = -1.8 × 10-6, at H* = 31 T hence presumably marks the crossover to a fluctuating nematic phase with large electronic nematic susceptibility. Magnetostriction quantum oscillations confirm a Fermi surface change at H* with the emergence of new orbits. By analyzing the field-induced change in the crystal-field ground state, we conclude that the in-plane Ce 4f hybridization is enhanced at H*, carrying the in-plane f-electron anisotropy to the Fermi surface. We argue that the nematic behavior observed in this prototypical heavy-fermion material is of electronic origin, and is driven by the hybridization between 4f and conduction electrons.