Ab-initio electronic and magnetic structure in La_0.66Sr_0.33MnO_3: strain and correlation effects

TL;DR

This study uses density-functional methods to analyze how tetragonal strain influences the electronic and magnetic properties of La_{2/3}Sr_{1/3}MnO_3, highlighting the importance of correlation effects and strain on half-metallicity and magnetic interactions.

Contribution

It demonstrates that LSDA+U accurately reproduces experimental electronic and magnetic properties, showing strain effects on orbital occupancy and magnetic coupling in La_{2/3}Sr_{1/3}MnO_3.

Findings

LSDA+U recovers half-metallicity consistent with experiments.

Strain slightly affects the minority gap by 0.1-0.2 eV.

Strain influences e_g orbital occupancy and magnetic coupling.

Abstract

The effects of tetragonal strain on electronic and magnetic properties of strontium-doped lanthanum manganite, La_{2/3}Sr_{1/3}MnO_3 (LSMO), are investigated by means of density-functional methods. As far as the structural properties are concerned, the comparison between theory and experiments for LSMO strained on the most commonly used substrates, shows an overall good agreement: the slight overestimate (at most of 1-1.5 %) for the equilibrium out-of-plane lattice constants points to possible defects in real samples. The inclusion of a Hubbard-like contribution on the Mn d states, according to the so-called "LSDA+U" approach, is rather ineffective from the structural point of view, but much more important from the electronic and magnetic point of view. In particular, full half-metallicity, which is missed within a bare density-functional approach, is recovered within LSDA+U, in agreement with experiments. Moreover, the half-metallic behavior, particularly relevant for spin-injection purposes, is independent on the chosen substrate and is achieved for all the considered in-plane lattice constants. More generally, strain effects are not seen to crucially affect the electronic structure: within the considered tetragonalization range, the minority gap is only slightly (i.e. by about 0.1-0.2 eV) affected by a tensile or compressive strain. Nevertheless, we show that the growth on a smaller in-plane lattice constant can stabilize the out-of-plane vs in-plane e_g orbital and significatively change their relative occupancy. Since e_g orbitals are key quantities for the double-exchange mechanism, strain effects are confirmed to be crucial for the resulting magnetic coupling.