Substrate-Dependence of Monolayer MoS$_2$ Thermal Conductivity and Thermal Boundary Conductance

TL;DR

This study investigates how different substrates influence the thermal conductivity and boundary conductance of monolayer MoS$_2$, revealing substrate-dependent variations and implications for device heat management.

Contribution

It provides a comprehensive comparison of thermal properties of MoS$_2$ on various substrates, highlighting substrate effects and independent tuning of TC and TBC.

Findings

MoS$_2$ TC varies significantly with substrate type.

h-BN buffer increases MoS$_2$ TC by up to 50%.

TBC differs notably between substrates, affecting heat removal.

Abstract

The thermal properties of two-dimensional (2D) materials, like MoS$_2$, are known to be affected by interactions with their environment, but this has primarily been studied only with SiO$_2$ substrates. Here, we compare the thermal conductivity (TC) and thermal boundary conductance (TBC) of monolayer MoS$_2$ on amorphous (a-) and crystalline (c-) SiO$_2$, AlN, Al$_2$O$_3$, and $\textit{h}$-BN monolayers using molecular dynamics. The room temperature TC of MoS$_2$ is ~38 Wm$^{-1}$K$^{-1}$ on amorphous substrates and up to ~68 Wm$^{-1}$K$^{-1}$ on crystalline substrates, with most of the difference due to substrate interactions with long-wavelength MoS$_2$ phonons (< 2 THz). An $\textit{h}$-BN monolayer used as a buffer between MoS$_2$ and the substrate causes the MoS$_2$ TC to increase by up to 50%. Length-dependent calculations reveal TC size effects below ~2 $\mu$m and show that the MoS$_2$ TC is size- but not substrate-limited below ~100 nm. We also find that the TBC of MoS$_2$ with c-Al$_2$O$_3$ is over twice that with c-AlN despite a similar MoS$_2$ TC on both, indicating that the TC and TBC could be tuned independently. Finally, we compare the thermal resistance of MoS$_2$ transistors on all substrates to show that MoS$_2$ TBC is the most important parameter for heat removal for long-channel (> 150 nm) devices, while TBC and TC are equally important for short channels. This work provides important insights for electro-thermal applications of 2D materials on various substrates.