Transmission through correlated CunCoCun heterostructures

Abstract

The effects of local electronic interactions and finite temperatures upon the transmission across the Cu4CoCu4 metallic heterostructure are studied in a combined density functional and dynamical mean field theory. It is shown that, as the electronic correlations are taken into account via a local but dynamic self-energy, the total transmission at the Fermi level gets reduced (predominantly in the minority spin channel), whereby the spin polarization of the transmission increases. The latter is due to a more significant d-electrons contribution, as compared to the non-correlated case in which the transport is dominated by s and p electrons.