Strain induced stabilization of a static Jahn-Teller distortion in the O*-phase of La7/8Sr1/8MnO3

Abstract

At room temperature, bulk La7/8Sr1/8MnO3 is in the dynamic Jahn--Teller O* phase, but undergoes a transition to a static, magnetically ordered Jahn--Teller phase at lower temperatures. Here we study a 6 unit cells thin film of this compound grown on SrTiO3, resulting in small compressive strain due to a lattice mismatch of 0.2\%. We combine X-ray absorption spectroscopy with multiplet ligand field theory to study the local electronic and magnetic properties of Mn in the film. We determine the Mn d3z2-r2 orbital to be 0.13\;eV lower in energy than the dx2-y2, which is a disproportionately large splitting given the small degree of compressive strain. We interpret this as resulting from the strain providing a preferential orientation for the MnO6 octahedra, which are strongly susceptible to such a deformation in the vicinity of the phase transition. Hence, they collectively elongate along the c axis into a static Jahn--Teller arrangement. Furthermore, we demonstrate the strongly covalent character of La7/8Sr1/8MnO3, with a contribution of nearly 50\% of the one-ligand-hole configuration d5 L1 to the ground state wavefunction. Finally, we find the system to be in a high-spin configuration, with the projection of the local magnetic moment on the quantization axis being about 3.7\;μB/Mn. We show, however, that the system is close to a high-spin--low-spin transition, which might be triggered by crystal field effects.