Tailoring Vacancies Far Beyond Intrinsic Levels Changes the Carrier Type and Optical Response in Monolayer MoSe2−x Crystals
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- 作者:Masoud Mahjouri-Samani ; Liangbo Liang ; Akinola Oyedele ; Yong-Sung Kim ; Mengkun Tian ; Nicholas Cross ; Kai Wang ; Ming-Wei Lin ; Abdelaziz Boulesbaa ; Christopher M. Rouleau ; Alexander A. Puretzky ; Kai Xiao ; Mina Yoon ; Gyula Eres ; Gerd Duscher ; Bobby G. Sumpter ; David B. Geohegan
- 刊名:Nano Letters
- 出版年:2016
- 出版时间:August 10, 2016
- 年:2016
- 卷:16
- 期:8
- 页码:5213-5220
- 全文大小:513K
- 年卷期:0
- ISSN:1530-6992
文摘
Defect engineering has been a critical step in controlling the transport characteristics of electronic devices, and the ability to create, tune, and annihilate defects is essential to enable the range of next-generation devices. Whereas defect formation has been well-demonstrated in three-dimensional semiconductors, similar exploration of the heterogeneity in atomically thin two-dimensional semiconductors and the link between their atomic structures, defects, and properties has not yet been extensively studied. Here, we demonstrate the growth of MoSeb>2–x b> single crystals with selenium (Se) vacancies far beyond intrinsic levels, up to ∼20%, that exhibit a remarkable transition in electrical transport properties from n- to p-type character with increasing Se vacancy concentration. A new defect-activated phonon band at ∼250 cm−1 appears, and the Ab>1g b> Raman characteristic mode at 240 cm−1 softens toward ∼230 cm−1 which serves as a fingerprint of vacancy concentration in the crystals. We show that post-selenization using pulsed laser evaporated Se atoms can repair Se-vacant sites to nearly recover the properties of the pristine crystals. First-principles calculations reveal the underlying mechanisms for the corresponding vacancy-induced electrical and optical transitions.