Interface phonon modes governing the ideal limit of thermal transport across diamond/cubic boron nitride interfaces

Abstract: Understanding the ideal limit of interfacial thermal conductance (ITC) across semiconductor heterointerfaces is crucial for optimizing heat dissipation in practical applications. By employing a highly accurate and efficient machine-learned potential trained herein, we perform extensive non-equilibrium molecular dynamics simulations to investigate the ITC of diamond/cubic boron nitride ($c$BN) interfaces. The ideal diamond/$c$BN interface exhibits an unprecedented ITC of 11.0 $\pm$ 0.1 GW m$^{-2}$ K$^{-1}$, setting a new upper bound for heterostructure interfaces. This exceptional conductance originates from extended phonon modes due to acoustic matching and localized C-atom modes that propagate through B-C bonds. However, atomic diffusion across the ideal interface creates mixing layers that disrupt these characteristic phonon modes, substantially suppressing the thermal transport from its ideal limit. Our findings reveal how interface phonon modes govern thermal transport across diamond/$c$BN interfaces, providing insights for thermal management in semiconductor devices.