Orbital-spin order and the origin of structural distortion in MgTi2O4

Abstract

We analyze electronic, magnetic, and structural properties of the spinel compound MgTi2O4 using the local density approximation+U method. We show how MgTi2O4 undergoes to a canted orbital-spin ordered state, where charge, spin and orbital degrees of freedom are frozen in a geometrically frustrated network by electron interactions. In our picture orbital order stabilize the magnetic ground state and controls the degree of structural distortions. The latter is dynamically derived from the cubic structure in the correlated LDA+U potential. Our ground-state theory provides a consistent picture for the dimerized phase of MgTi2O4, and might be applicable to frustrated materials in general.