Thermal Conductivity of BAs under Pressure.

Boron arsenide (BAs) is an ultrahigh thermal conductivity material with special phonon-phonon scattering properties. At ambient pressure, the bunching of acoustic phonon branches in BAs leads to a small phase-space for three-phonon scattering. Density functional theory predicts that this acoustic phonon bunching effect is sensitive to pressure. To explore this physics, we measure the thermal conductivity of BAs from 0 to 25 GPa using time-domain thermoreflectance in a diamond anvil cell. We characterized two BAs samples with ambient thermal conductivities of 320 and 480 W m-1 K-1. Our experiments show that the thermal conductivity of both samples depends weakly on pressure from 0 to 25 GPa. We attribute the weak dependence of the thermal conductivity of BAs on pressure to the weak pressure dependence of phonon-phonon scattering rates. Our experimental results are consistent with DFT predictions that three-phonon scattering rates increase from 0 to 25 GPa, while four-phonon scattering rates decrease.