Exceptional Optical Phonon Coherence in Enriched Cubic Boron Arsenide via Suppression of Three-Phonon Scattering

TL;DR

This study demonstrates near-elimination of three-phonon scattering in enriched cubic boron arsenide, achieving record-high phonon coherence and providing insights into phonon scattering mechanisms for advanced thermal management.

Contribution

It reveals that isotope enrichment can nearly eliminate three-phonon scattering in BAs, significantly enhancing phonon coherence and advancing understanding of phonon transport limits.

Findings

Record-high phonon quality factor above 3.7×10^3 in enriched BAs.

Defect scattering is negligible compared to isotope scattering in optical phonon linewidths.

Three-phonon scattering is nearly eliminated for zone-center optical phonons below 100 K.

Abstract

Cubic boron arsenide (BAs) is a promising semiconductor for next-generation electronics due to its outstanding ambipolar mobility and thermal conductivity, the latter of which is attributed to the suppression of three-phonon scattering. However, precisely accounting for different high-order anharmonic scattering processes is challenging from both theory and experiment, so that questions remain open regarding the ultimate limit of phonon lifetime and thermal conductivity in BAs. Here we show that this gap nearly eliminates three-phonon scattering for zone-center optical phonons in a wide temperature range, leading to a record-high, isotope purity-limited phonon coherence with a quality factor above $3.7\times 10^3$ for >98% enriched $^{11}$BAs below 100 K. We discriminate three decoherence mechanisms by their temperature-dependent contribution to the damping rate using high-resolution Raman and Fourier transform infrared spectroscopy. For the as-synthesized crystals, we find that defect scattering has negligible contributions to the linewidth of optical phonons in comparison to isotope scattering. These results provide critical insights into the intrinsic and extrinsic scattering mechanisms of optical phonons in BAs, motivating further studies to quantify anharmonic effects and realize superior phonon transport.