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Ultrafast photocarrier dynamics related to defect states of Si 1−x Ge x nanowires measured by optical pump–THz probe spectroscopy

2017; Royal Society of Chemistry; Volume: 9; Issue: 23 Linguagem: Inglês

10.1039/c7nr00761b

2040-3372

Jung Min Bae, Woo Jung Lee, Seonghoon Jung, Jin Won, Kwangsik Jeong, Seung Hoon Oh, Seongsin M. Kim, Dong Chan Suh, Woo-Bin Song, Sunjung Kim, Jaehun Park, Mann‐Ho Cho,

Chalcogenide Semiconductor Thin Films

Slightly tapered Si1−xGex nanowires (NWs) (x = 0.29–0.84) were synthesized via a vapor–liquid–solid procedure using Au as a catalyst. We measured the optically excited carrier dynamics of Si1−xGex NWs as a function of Ge content using optical pump–THz probe spectroscopy. The measured −ΔT/T0 signals of Si1−xGex NWs were converted into conductivity in the THz region. We developed a fitting formula to apply to indirect semiconductors such as Si1−xGex, which explains the temporal population of photo-excited carriers in the band structure and the relationship between the trapping time and the defect states on an ultrafast time scale. From the fitting results, we extracted intra- and inter-valley transition times and trapping times of electrons and holes of Si1−xGex NWs as a function of Ge content. On the basis of theoretical reports, we suggest a physical model to interpret the trapping times related to the species of interface defect states located at the oxide/NW: substoichiometric oxide states of Si(Ge)0+,1+,2+, but not Si(Ge)3+, could function as defect states capturing photo-excited electrons or holes and could determine the different trapping times of electrons and holes depending on negatively or neutrally charged states.