# Half-Heusler Compounds: Promising Materials For Mid-To-High Temperature   Thermoelectric Conversion

**Authors:** S. Joseph Poon

arXiv: 1905.03845 · 2020-01-08

## TL;DR

Half-Heusler compounds are promising thermoelectric materials for intermediate temperatures, with recent advancements increasing their efficiency and power output, driven by innovative approaches since 2012.

## Contribution

This paper provides a historical overview and categorization of half-Heusler materials into three generations, highlighting recent improvements in thermoelectric performance.

## Key findings

- ZT increased from ~1 to 1.5 since 2012
- Thermoelectric modules achieve near 10% efficiency
- Power density reaches approximately 9 W/cm2

## Abstract

Half-Heusler compounds (space group Fm3m) has garnered increasing attention in recent years in the thermoelectric community. Three decades ago, refractory RNiSn half-Heusler compounds (R represents refractory metals such as Hf, Zr, Ti) were found to be narrow-gap semiconductors with large Seebeck coefficients in 100s of micro-volt per Kelvin. Today, half-Heusler (HH) compounds have emerged as promising thermoelectric materials in the intermediate temperature range (400-800oC). HH materials are endowed with good thermal stability and scalability. Thermoelectric n-p modules based on HH materials demonstrate conversion efficiency near 10% and power density output near 9 W/cm2. The objective of this article is to present a historical account of the research and development of thermoelectric half-Heusler compounds. Particularly, there have been notable achievements since 2012 thanks to the emergence of new approaches. As a result, ZT has risen from ~1 to 1.5. The various advances made since the early 1990s to the present are recounted by categorizing half-Heusler materials into three generations (Gen): Gen-1 Gen-2, and Gen-3 HH materials.

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Source: https://tomesphere.com/paper/1905.03845