Abstract
Half-Heusler (HH) alloys are an important class of thermoelectric materials that combine promising performance with good engineering properties. This manuscript reports a variable temperature synchrotron x-ray diffraction study of several TiNiSn- and VFeSb-based HH alloys. A Debye model was found to capture the main trends in thermal expansion and atomic displacement parameters. The linear thermal expansion coefficient α(T) of the TiNiSn-based samples was found to be independent of alloying or presence of Cu interstitials with α av = 10.1 × 10−6 K−1 between 400 and 848 K. The α(T) of VFeSb and TiNiSn are well-matched, but NbFeSb has a reduced α av = 8.9 × 10−6 K−1, caused by a stiffer lattice structure. This is confirmed by analysis of the Debye temperatures, which indicate significantly larger bond force constants for all atomic sites in NbFeSb. This work also reveals substantial amounts of Fe interstitials in VFeSb, whilst these are absent for NbFeSb. The Fe interstitials are linked to low thermal conductivities, but also reduce the bandgap and lower the onset of thermal bipolar transport.
Highlights
27 April 2021Half-Heusler (HH) alloys are an important class of thermoelectric materials that combine promising performance with good engineering properties
Thermoelectric generators (TEGs) use arrays of n- and p-type semiconductors to convert waste heat into electricity and are a renewable energy technology that improves fossil fuel utilisation [1]
HH compositions Variable temperature synchrotron x-ray powder diffraction (SXRD) patterns for TiNiSn collected between 295 and 848 K are shown in figure 1, whilst equivalent plots for the other compositions can be found in figures S1–S5 in the supplemental information
Summary
Half-Heusler (HH) alloys are an important class of thermoelectric materials that combine promising performance with good engineering properties. This manuscript reports a variable temperature synchrotron x-ray diffraction study of several TiNiSn- and VFeSb-based HH alloys. The α(T) of VFeSb and TiNiSn are well-matched, but NbFeSb has a reduced αav = 8.9 × 10−6 K−1, caused by a stiffer lattice structure This is confirmed by analysis of the Debye temperatures, which indicate significantly larger bond force constants for all atomic sites in NbFeSb. This work reveals substantial amounts of Fe interstitials in VFeSb, whilst these are absent for NbFeSb. The Fe interstitials are linked to low thermal conductivities, and reduce the bandgap and lower the onset of thermal bipolar transport
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