Exposing the hidden influence of selection rules on phonon-phonon scattering by pressure and temperature tuning

Selection rules act to restrict the intrinsic anharmonic interactions between phonons in all crystals. Yet their influence on phonon propagation is hidden in most materials and so, hard to interrogate experimentally. Using ab initio calculations, we show that the otherwise invisible impact of selection rules on three-phonon scattering can be exposed through anomalous signatures in the pressure (P) and temperature (T) dependence of the thermal conductivities, kappa, of certain compounds. Boron phosphide reveals such underlying behavior through an exceptionally sharp initial rise in kappa with increasing P, which may be the steepest of any material, and also a peak and decrease in kappa at high P. These features are in stark contrast to the measured behavior for many solids, and they occur at experimentally accessible conditions. These findings give a deep understanding of phonon lifetimes and heat conduction in solids, and motivate experimental efforts to observe the predicted behavior. In most compounds, a roughly linear rise in thermal conductivity (k) with pressure (P) is observed. Here, the authors predict boron phosphide exhibits what may be the steepest rise in k with P of any compound followed by a peak and drop in k due to the action of phonon-scattering selection rules.

Automated summary

Selection rules have a significant impact on three-phonon scattering in certain compounds, revealing anomalous behavior in the pressure and temperature dependence of thermal conductivities. Boron phosphide shows sharp initial rise and peak-drop patterns in thermal conductivity with pressure, contrasting with the behavior of many solids, and these findings motivate further experimental efforts.