# Thermoelectric transport trends in group 4 half-Heusler alloys

**Authors:** Kristian Berland, Nina Shulumba, Olle Hellman, Clas Persson, and Ole Martin L{\o}vvik

arXiv: 1907.02845 · 2020-01-08

## TL;DR

This study uses first-principles calculations to analyze thermoelectric properties of group 4 half-Heusler alloys, revealing key factors affecting their efficiency and identifying promising compositions for thermoelectric applications.

## Contribution

It provides a comprehensive first-principles analysis of thermoelectric trends in group 4 half-Heusler alloys, highlighting the effects of alloying, scattering, and functional choice on thermoelectric performance.

## Key findings

- ZrNiSn, ZrCoSb, ZrCoBi alloys show promising thermoelectric properties.
- Sub-lattice disorder on the Z-site is more effective for reducing thermal conductivity.
- Choice of functional significantly influences predicted thermoelectric properties.

## Abstract

The thermoelectric properties of 54 different group 4 half-Heusler (HH) alloys have been studied from first principles. Electronic transport was studied with density functional theory using hybrid functionals facilitated by the $\mathbf{k} \cdot \mathbf{p}$ method, while the temperature dependent effective potential method was used for the phonon contributions to the figure of merit $ZT$. The phonon thermal conductivity was calculated including anharmonic phonon-phonon, isotope, alloy and grain-boundary scattering. HH alloys have an ${\it XYZ}$ composition and those studied here are in the group 4-9-15 (Ti,Zr,Hf)(Co,Rh,Ir)(As,Sb,Bi) and group 4-10-14 (Ti,Zr,Hf)(Ni,Pd,Pt)(Ge,Sn,Pb). The electronic part of the thermal conductivity was found to significantly impact $ZT$ and thus the optimal doping level. Furthermore, the choice of functional was found to significantly affect thermoelectric properties, particularly for structures exhibiting band alignment features. The intrinsic thermal conductivity was significantly reduced when alloy and grain boundary scattering were accounted for, which also reduced the spread in thermal conductivity. It was found that sub-lattice disorder on the ${\it Z}$-site, i.e. the site occupied by group 14 or 15 elements, was more effective than ${\it X}$-site substitution, occupied by group 4 elements. The calculations confirmed that ZrNiSn, ZrCoSb and ZrCoBi based alloys display promising thermoelectric properties. A few other n-type and p-type compounds were also predicted to be potentially excellent thermoelectric materials, given that sufficiently high charge carrier concentrations can be achieved. This study provides insight into the thermoelectric potential of HH alloys and casts light on strategies to optimize thermoelectric performance of multicomponent alloys.

## Full text

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## Figures

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## References

88 references — full list in the complete paper: https://tomesphere.com/paper/1907.02845/full.md

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Source: https://tomesphere.com/paper/1907.02845