Theoretical evidence of spin-orbital-entangled Jeff=1/2 state in the 3d transition metal oxide CuAl2O4

Abstract

Transition metal oxides exhibit various competing phases and exotic phenomena depending on how their reaction to the rich degeneracy of the d-orbital. Large spin-orbit coupling (SOC) reduces this degeneracy in a unique way by providing a spin-orbital-entangled ground state for 4d and 5d transition metal compounds. In particular, the spin-orbital-entangled Kramers doublet, known as the Jeff=1/2 pseudospin, appears in layered iridates and α-RuCl3, manifesting a relativistic Mott insulating phase. Such entanglement, however, seems barely attainable in 3d transition metal oxides, where the SOC is small and the orbital angular momentum is easily quenched. From experimental and theoretical evidence, here we report on the CuAl2O4 spinel as the first example of a Jeff=1/2 Mott insulator in 3d transition metal compounds. Based on the experimental study, including synthesis of the cubic CuAl2O4 single crystal, density functional theory and dynamical mean field theory calculations reveal that the Jeff=1/2 state survives the competition with an orbital-momentum-quenched S=1/2 state. The electron-addition spectra probing unoccupied states are well described by the jeff=1/2 hole state, whereas electron-removal spectra have a rich multiplet structure. The fully relativistic entity found in CuAl2O4 provides new insight into the untapped regime where the spin-orbital-entangled Kramers pair coexists with strong electron correlation.