Magnon-assisted transport and thermopower in ferromagnet-normal metal tunnel junctions

Abstract

We develop a theoretical model of magnon-assisted transport in a mesoscopic tunnel junction between a ferromagnetic metal and a normal (non-magnetic) metal. The current response to a bias voltage is dominated by the contribution of elastic processes rather than magnon-assisted processes and the degree of spin polarization of the current, parameterized by a function P ( (),N), 0 ≤ P ≤ 1, depends on the relative sizes of the majority and minority band Fermi surface in the ferromagnet and of the Fermi surface of the normal metal N. On the other hand, magnon-assisted tunneling gives the dominant contribution to the current response to a temperature difference across the junction. The resulting thermopower is large, S - (kB/e) (kBT/ωD)3/2 P ( (),N), where the temperature dependent factor (kBT/ωD)3/2 reflects the fractional change in the net magnetization of the ferromagnet due to thermal magnons at temperature T (Bloch's T3/2 law) and ωD is the magnon Debye energy.

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