Abstract

Temperature-dependent photoreflectance (PR) measurements for Ge0.938Sn0.062/Ge/Si films treated with a hydrogen inductively coupled plasma (H2-ICP) have been performed. The Ge0.938Sn0.062 film is grown on Ge-buffered Si substrate by ultra-high vacuum chemical vapor deposition method, and the H2-ICP treatment was carried out for 5min for the Ge0.938Sn0.062 epitaxial layer. The high-resolution X-ray diffraction results show that the compressive strain of the Ge0.938Sn0.062 layer decreases and the tensile strain of the Ge buffer layer increases after H2-ICP treatment. The PR spectrum of as-grown Ge0.938Sn0.062/Ge/Si film at 300K consists of three signals at 0.603, 0.782 and 0.814eV, which are assigned to the direct transitions from conduction Γ valley to the valence bands related to the surface of Ge0.938Sn0.062, the Ge/Si and GeSn/Ge interfaces, respectively. After H2-ICP treatment, two PR signals of 0.604 and 0.781eV were obtained at 300K and they are attributed to the direct transition energies of the Ge0.938Sn0.062 and the Ge buffer layer, respectively. As temperature decreases, new weak PR signals appear in the lower energy regions of both PR signals from the H2-ICP treated GeSn and Ge layers at 210K and 130K, respectively, due to the increase of tensile strain in Ge layer while no new signal appears for the as-grown sample. The PR spectrum of the H2-ICP treated sample at 10K shows four signals, and these signals are assigned to the surface of GeSn and GeSn at the interface between GeSn and Ge buffer layers, the Ge at the interface between GeSn and Ge buffer layers, and the Ge at the interface between Ge buffer layer and Si substrate, respectively. These PR results indicate that H2-ICP treatment significantly affects the strain and defects near the interface between GeSn and Ge layers, and thus optical properties of GeSn layer are also altered by H2-ICP treatment.

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