Experimental Evidence of Superdiffusive Thermal Transport in Si<sub>0.4</sub>Ge<sub>0.6</sub> Thin Films
Fengju Yao, Shunji Xia, Haoxiang Wei, Jiongzhi Zheng, Ziyuan Yuan, Yusheng Wang, Baoling Huang, Deyu Li, Hong Lü, Dongyan Xu
Abstract
Superdiffusive thermal transport represents a unique phenomenon in heat conduction, which is characterized by a size (L) dependence of thermal conductivity (κ) in the form of κ ∝ Lβ with a constant β between 0 and 1. Although superdiffusive thermal transport has been theoretically predicted for SiGe alloys, direct experimental evidence is still lacking. Here, we report on a systematic experimental study of the thickness-dependent thermal conductivity of Si0.4Ge0.6 thin films grown by molecular beam epitaxy. The cross-plane thermal conductivity of Si0.4Ge0.6 thin films spanning a thickness range from 20 to 1120 nm was measured in the temperature range 120–320 K via a differential three-omega method. Results show that the thermal conductivity follows a consistent κ ∝ t0.26 power law with the film thickness (t) at different temperatures, providing direct experimental evidence that alloy-scattering dominated thermal transport in SiGe is superdiffusive.