Spin Seebeck Effect: Sensitive Probe for Elementary Excitation, Spin Correlation, Transport, Magnetic Order, and Domains in Solids

TL;DR

The paper reviews the spin Seebeck effect (SSE) as a versatile tool for probing magnetic properties, including excitations, order, and spin transport, across various magnetic materials and discusses recent advances and nuclear SSE.

Contribution

It provides a comprehensive overview of recent progress in using SSE to investigate magnetic properties and introduces the concept of nuclear SSE as a new probe.

Findings

SSE reflects elementary excitations and magnetic order.

SSE occurs in diverse magnetic materials including ferro-, ferri-, and antiferromagnets.

Recent discovery of nuclear SSE expands its applications.

Abstract

The spin Seebeck effect (SSE) refers to the generation of a spin current as a result of a temperature gradient in a magnetic material, which can be detected electrically via the inverse spin Hall effect in a metallic contact. Since the discovery of SSE in 2008, intensive studies on SSE have been conducted to elucidate its origin. SSEs appear in a wide range of magnetic materials including ferro-, ferri-, and antiferro-magnets and also paramagnets with classical or quantum spin fluctuation. SSE voltage reflects fundamental properties of a magnet, such as elementary excitation, static magnetic order, spin correlation, and spin transport. In this article, we review recent progress on SSEs in various systems, with particular emphasis on its emerging role as a probe of these magnetic properties in solids. We also briefly discuss the recently-discovered nuclear SSE.