Thermal and Vibrational Properties of Thermoelectric ZnSb - Exploring the Origin of Low Thermal Conductivity

TL;DR

This study investigates the low thermal conductivity of ZnSb by combining experimental and theoretical methods, revealing anharmonic vibrations and low-energy optical phonons as key factors, which may also influence similar thermoelectric materials.

Contribution

The paper provides a comprehensive analysis of ZnSb's vibrational properties and identifies the mechanisms behind its low thermal conductivity, integrating experimental data with first-principles calculations.

Findings

ZnSb exhibits increasingly anharmonic behavior of Zn atoms with temperature.

Presence of low-energy optical phonon modes below 60 cm-1.

Low thermal conductivity is linked to coupling of optical modes with acoustic phonons.

Abstract

The intermetallic compound ZnSb is an interesting thermoelectric material, largely due to its low lattice thermal conductivity. The origin of the low thermal conductivity has so far been speculative. Using multi-temperature single crystal X-ray diffraction (9 - 400 K) and powder X-ray diffraction (300 - 725 K) measurements we characterized the volume expansion and the evolution of structural properties with temperature and identify an increasingly anharmonic behavior of the Zn atoms. From a combination of Raman spectroscopy and first principles calculations of phonons we consolidate the presence of low-energy optic modes with wavenumbers below 60 cm-1. Heat capacity measurements between 2 and 400 K can be well described by a Debye-Einstein model containing one Debye and two Einstein contributions with temperatures {\Theta}D = 195K, {\Theta}E1 = 78 K and {\Theta}E2 = 277 K as well as a significant contribution due to anharmonicity above 150 K. The presence of a multitude of weakly dispersed low-energy optical modes (which couple with the acoustic, heat carrying phonons) combined with anharmonic thermal behavior provides an effective mechanism for low lattice thermal conductivity. The peculiar vibrational properties of ZnSb are attributed to its chemical bonding properties which are characterized by multicenter bonded structural entities. We argue that the proposed mechanism to explain the low lattice thermal conductivity of ZnSb might also control the thermoelectric properties of electron poor semiconductors, such as Zn4Sb3, CdSb, Cd4Sb3, Cd13-xInyZn10, and Zn5Sb4In2-x.