Antisite pairs suppress the thermal conductivity of BAs

TL;DR

This study identifies antisite pairs as the main defects reducing the thermal conductivity of boron arsenide (BAs), explaining the discrepancy between predicted and measured values and suggesting ways to improve crystal quality.

Contribution

It provides atomic-scale evidence of antisite defects in BAs and demonstrates their significant impact on thermal conductivity, advancing understanding of defect-related thermal transport.

Findings

Antisite pairs are the primary defects in BAs.

Antisite defects significantly lower thermal conductivity.

Estimated thermal conductivity aligns with experimental measurements.

Abstract

BAs was predicted to have an unusually high thermal conductivity at room temperature of 2000$\,$Wm$^{-1}$$\,$K$^{-1}$, comparable to that of diamond. However, the experimentally measured thermal conductivity of BAs single crystals is an order of magnitude lower. To identify the origin of this large inconsistency, we investigated the lattice structure and potential defects in BAs single crystals at atomic scale using aberration-corrected scanning transmission electron microscopy (STEM). Rather than finding a large concentration As vacancies ($V_\mathrm{As}$), as widely thought to dominate the thermal resistance in BAs crystals, our STEM results showed enhanced intensity of some B columns and reduced intensity of some As columns, suggesting the presence of antisite defects with As$_\mathrm{B}$ (As-atom on B site) and B$_\mathrm{As}$ (B-atom on As site) with significant concentrations. Further calculations show that the antisite pair with As$_\mathrm{B}$ next to B$_\mathrm{As}$ is preferred energetically among the different types of point defects investigated, and confirm that such defects lower the thermal conductivity for BAs. Using a concentration of 6.6$\pm$3$\times$10$^{20}$$\,$cm$^{-3}$ for the antisite pairs estimated from STEM images, thermal conductivity is estimated to be 65-100$\,$Wm$^{-1}$$\,$K$^{-1}$, in reasonable agreement with our measured value. Our study suggests that As$_\mathrm{B}$-B$_\mathrm{As}$ antisite pairs are the primary lattice defects suppressing thermal conductivity of BAs. Possible approaches are proposed for growth of high quality crystals or films with high thermal conductivity.