Magnons versus electrons in thermal spin transport through metallic interfaces

Abstract

We develop a theory for spin transport in magnetic metals that treats the contribution of magnons and electrons on equal footing. As an application we consider thermally-driven spin injection across an interface between a magnetic metal and a normal metal, i.e., the spin-dependent Seebeck effect. We show that the ratio between magnonic and electronic contribution scales as T/TCTF/TC, with the Fermi temperature TF and the Curie temperature TC. Since, typically, TC TF, the magnonic contribution may dominate the thermal spin injection, even though the interface is more transparent for electronic spin current.