Thermal effects in spintronic materials and devices: an experimentalist's guide

TL;DR

This paper offers an intuitive framework for understanding thermal gradients in spintronic devices, emphasizing their commonality and impact on experimental measurements, and reviews related thermoelectric effects and ongoing challenges.

Contribution

It introduces simple tools to analyze thermal gradients in thin film spintronic systems and highlights their significance in experimental and device contexts.

Findings

Thermal gradients perpendicular to thin films are very common.

The largest temperature drops occur across the bulk substrate.

Thermoelectric effects can generate measurable voltage signals.

Abstract

Research in spintronics often involves generation of heat in nanoscale magnetic systems. This heat generation can be intentional, as when studying effects created by an external applied temperature difference, or unintentional, coming as a consequence of driving relatively large charge currents through tiny structures. Understanding and controlling these thermal gradients can present challenges to experimentalists, which are related at some level to the fact that heat flow is much more difficult to isolate and manipulate than charge flow. This paper aims to provide a simple, intuitive framework to understand the fundamental issues that arise in spintronic materials and devices involving thermal gradients. The first goal is to provide simple tools to demonstrate how thermal gradients arise in systems with thin conducting films on bulk substrates. The main results are that a thermal gradient pointing perpendicular to the plane of a thin film supported on a macroscopic substrate is very common, even while the largest temperature drop in the system will exist across the bulk substrate itself. These results point to the need to understand the range of thermoelectric and magnetothermoelectric effects that can generate voltage signals and other responses to thermal gradients. I provide a brief review of these, along with relevant spin effects. The review concludes with examples and comments on several important ongoing issues in spintronics where thermal gradients play key roles.