Inducing n- and p-type thermoelectricity in oxide superlattices by strain tuning of orbital-selective transport resonances

Abstract

By combining first-principles simulations including an on-site Coulomb repulsion term and Boltzmann theory, we demonstrate how the interplay of quantum confinement and epitaxial strain allows to selectively design n- and p-type thermoelectric response in (LaNiO3)3/(LaAlO3)1(001) superlattices. In particular, varying strain from -4.9 to +2.9\% tunes the Ni orbital polarization at the interfaces from -6 to +3\%. This is caused by an electron redistribution among Ni 3dx2-y2- and 3dz2-derived quantum well states which respond differently to strain. Owing to this charge transfer, the position of emerging cross-plane transport resonances can be tuned relative to the Fermi energy. Already for moderate values of 1.5 and 2.8\% compressive strain, the cross-plane Seebeck coefficient reaches -60 and +100 μV/K around room temperature, respectively. This provides a novel mechanism to tailor thermoelectric materials.