Carbon Trends (Oct 2021)
First principles investigation of high thermal conductivity in hexagonal germanium carbide(2H-GeC)
Abstract
Designing and searching for a high thermal conductivity material in both bulk and nanoscale is highly demanding for electronics cooling. In this work, we studied the thermal conductivity of 2H-Germanium Carbide(2H-GeC) using first principles calculations. At 300 K, we are reporting a high thermal conductivity of 1350 Wm−1K−1 and 1050 Wm−1K−1 along a-axis and c-axis respectively for pure 2H-GeC. These values are 130% higher than the thermal conductivity of 2H-silicon carbide and 20% lower than cubic germanium carbide(c-GeC). We analyzed the phonon group velocities, phonon scattering rates and mode contribution from acoustic and optical phonons. We also studied the thermal conductivity of nanostructured 2H-GeC for heat dissipation in nanoelectronics. At room temperature, thermal conductivity of 2H-GeC is ∼65 Wm−1K−1 at nanometer length scales(L) of 100 nm is equal to that of the c-GeC. This result suggests that, 2H-GeC will be a promising material for thermal management applications in micro/nano electronics.
