激子
材料科学
双层
化学物理
工作(物理)
光电子学
沉积(地质)
异质结
密度泛函理论
纳米技术
电荷(物理)
超晶格
态密度
化学气相沉积
凝聚态物理
带隙
过渡金属
分子物理学
扭转
辐射传输
电荷密度
作者
Jianhui Zhou,Hongmei Zhang,Liang Li,Zhike Peng,Bowen Yao,Yayun Yu,Zengfu Li,Qian Xu,Wei Luo,Chuyun Deng,Gang Peng,Guang Wang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-12-19
卷期号:20 (1): 1538-1547
标识
DOI:10.1021/acsnano.5c18483
摘要
Twisted bilayer transition metal dichalcogenides (TB-TMDs) have emerged as a versatile platform for fabricating moiré superlattices and exploring correlated electronic behavior, particularly in revealing the interplay between exciton dynamics and twisted angles. However, the direct synthesis of high-quality TB-TMDs nanosheets has been hindered by thermodynamic instability. Here, we develop an oxygen-assisted physical vapor deposition strategy to directly synthesize TB-MoS2 nanosheets with twist-angle-dependent exciton dynamics. First-principles calculations reveal that oxygen incorporation significantly reduces the formation energy of TB-MoS2. Guided by this analysis, an oxygen-modulated precursor system is successfully designed to synthesize high-quality TB-MoS2 nanosheets with well-defined moiré patterns and a broad angular distribution. Besides, for A exciton, it is demonstrated that the time constant t2 corresponding to the radiative recombination process is shorter at the twist angles of 0° and 60° compared to 12°, 24°, 40°, and 47°. This result is attributed to reduced interlayer distance and enhanced interlayer coupling, as supported by differential charge density and density of states calculations. Furthermore, t2 is shorter at 24° and 40° than at 12° and 47°, owing to a smaller energy difference between indirect and direct bandgaps. Our work not only establishes an effective route for fabricating TB-TMDs but also deepens the understanding of twist-angle-engineered moiré photonics.
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