Thermoelectric films and periodic structures and spin Seebeck effect systems: Facets of performance optimization

TL;DR

This review discusses recent advancements in thermoelectric and spin Seebeck effect systems, focusing on material fabrication, microstructure control, and performance optimization for energy harvesting applications.

Contribution

It provides a comprehensive analysis of fabrication techniques, material properties, and recent developments in TE films and SSE systems, highlighting strategies for performance enhancement.

Findings

High-performance TE films achieved through microstructure control.

Enhanced spin Seebeck signals via system design and interface optimization.

Strategies identified for increasing thermoelectric figure of merit (zT).

Abstract

The growing market for sensors, internet of things, and wearable devices is fueling the development of low-cost energy-harvesting materials and systems. Film based thermoelectric (TE) devices offer the ability to address the energy requirements by using ubiquitously available waste-heat. This review narrates recent advancements in fabricating high-performance TE films and superlattice structures, from the aspects of microstructure control, doping, defects, composition, surface roughness, substrate effect, interface control, nanocompositing, and crystal preferred orientation realized by regulating various deposition parameters and subsequent heat treatment. The review begins with a brief account of heat conduction mechanism, quantum confinement effect in periodic layers, film deposition processes, thin film configurations and design consideration for TE in-plane devices, and characterization techniques. It then proceeds to alayzing the latest findingd on the TE properties of Bi2(Te,Se)3 and (Bi,Sb)2Te3, PbTe, GeTe, SnSe, SnTe, Cu2-xSe, and skutterudite films, including superlattices and the performance of TE generators, sensors, and cooling devices. Thickness dependent microstructure evolution and TE characteristics of films in relation to temperature are also analyzed. In the context of spin Seebeck effect (SSE) based systems, SSE mechanism analysis, developments in enhancing the spin Seebeck signal since its first observation, and recent developments are covered from the facets of new system design, signal collection, magnetic manipulation, interface conditions, thickness-dependent longitudinal spin Seebeck signal, and length scale of phonon and magnon transport in longitudinal SSE (LSSE) in different bi-layer systems. At the end, possible strategies for further enhancing zT of TE films and spin Seebeck signals of many systems are addressed.