Two-dimensional layered MSiN (M = Mo, W) as promising thermal management materials: a comparative study.

With the miniaturization and integration of nanoelectronic devices, efficient heat removal becomes a key factor affecting their reliable operation. Two-dimensional (2D) materials, with high intrinsic thermal conductivity, good mechanical flexibility, and precisely controllable growth, are widely accepted as ideal candidates for thermal management materials. In this work, by solving the phonon Boltzmann transport equation (BTE) based on first-principles calculations, we investigated the thermal conductivity of novel 2D layered MSiN (M = Mo, W). Our results point to a competitive thermal conductivity as large as 162 W m K of monolayer MoSiN, which is around two times larger than that of WSiN and seven times larger than that of monolayer MoS despite their similar non-planar structures. It is revealed that the high thermal conductivity arises mainly from its large group velocity and low anharmonicity. Our result suggests that MoSiN could be a potential candidate for 2D thermal management materials.