Quantum spin transport and dynamics through a novel F/N junction

TL;DR

This paper investigates spin wave propagation and magnetization transport across a ferromagnetic/normal metal junction at low temperatures, proposing experimental detection methods and potential spintronic applications.

Contribution

It introduces a detailed analysis of spin wave modes and boundary conditions in F/N junctions, highlighting novel spin transport phenomena in the precession-dominated regime.

Findings

Identification of spin wave modes on both sides of the junction.

Proposal of a CESR experiment to detect spin wave propagation.

Potential applications in spintronic devices based on spin transport features.

Abstract

We study the spin transport in the low temperature regime (often referred to as the precession-dominated regime) between a ferromagnetic Fermi liquid (FFL) and a normal metal metallic Fermi liquid (NFL), also known as the F/N junction, which is considered as one of the most basic spintronic devices. In particular, we explore the propagation of spin waves and transport of magnetization through the interface of the F/N junction where nonequilibrium spin polarization is created on the normal metal side of the junction by electrical spin injection. We calculate the probable spin wave modes in the precession-dominated regime on both sides of the junction especially on the NFL side where the system is out of equilibrium. Proper boundary conditions at the interface are introduced to establish the transport of the spin properties through the F/N junction. A possible transmission conduction electron spin resonance (CESR) experiment is suggested on the F/N junction to see if the predicted spin wave modes could indeed propagate through the junction. Potential applications based on this novel spin transport feature of the F/N junction are proposed in the end.