An atomistic Green’s function method is developed to simulate phonon transport across a strained germanium (or silicon) thin film between two semi-infinite silicon (or germanium) contacts. A plane-wave formulation is employed to handle the translational symmetry in directions parallel to the interfaces. The phonon transmission function and thermal conductance across the thin film are evaluated for various atomic configurations. The contributions from lattice straining and material heterogeneity are evaluated separately, and their relative magnitudes are characterized. The dependence of thermal conductance on film thickness is also calculated, verifying that the thermal conductance reaches an asymptotic value for very thick films. The thermal boundary resistance of a single SiGe interface is computed and agrees well with analytical model predictions. Multiple-interface effects on thermal resistance are investigated, and the results indicate that the first few interfaces have the most significant effect on the overall thermal resistance.

Issue Section:
Micro/Nanoscale Heat Transfer
Keywords:
silicon, germanium, elemental semiconductors, semiconductor thin films, semiconductor heterojunctions, interface phonons, thermal conductivity, Green's function methods, electron-phonon interactions, phonon spectra
Topics:
Green's function methods, Phonons, Silicon, Thermal conductivity, Thin films, Germanium, Interfacial thermal resistance, Thermal resistance, Simulation, Temperature, Waves
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