Your search keyword '"Ji, Hongjia"' showing total 2 results

1. Reconfiguring nucleation for CVD growth of twisted bilayer MoS2 with a wide range of twist angles.

Author

Xu, Manzhang, Ji, Hongjia, Zheng, Lu, Li, Weiwei, Wang, Jing, Wang, Hanxin, Luo, Lei, Lu, Qianbo, Gan, Xuetao, Liu, Zheng, Wang, Xuewen, and Huang, Wei

Subjects

SUPERLATTICES, DISCONTINUOUS precipitation, ELECTRONIC band structure, CONDENSED matter physics, CHEMICAL vapor deposition, ANGLES, BIOELECTRONICS, BILAYER lipid membranes

Abstract

Twisted bilayer (TB) transition metal dichalcogenides (TMDCs) beyond TB-graphene are considered an ideal platform for investigating condensed matter physics, due to the moiré superlattices-related peculiar band structures and distinct electronic properties. The growth of large-area and high-quality TB-TMDCs with wide twist angles would be significant for exploring twist angle-dependent physics and applications, but remains challenging to implement. Here, we propose a reconfiguring nucleation chemical vapor deposition (CVD) strategy for directly synthesizing TB-MoS2 with twist angles from 0° to 120°. The twist angles-dependent Moiré periodicity can be clearly observed, and the interlayer coupling shows a strong relationship to the twist angles. Moreover, the yield of TB-MoS2 in bilayer MoS2 and density of TB-MoS2 are significantly improved to 17.2% and 28.9 pieces/mm2 by tailoring gas flow rate and molar ratio of NaCl to MoO3. The proposed reconfiguring nucleation approach opens an avenue for the precise growth of TB-TMDCs for both fundamental research and practical applications. Twisted bilayers of 2D semiconductors are being intensively investigated due to their emergent physical properties, but their controlled bottom-up synthesis remains challenging. Here, the authors report a confined-space chemical vapour deposition strategy to synthesize MoS2 bilayers with twist angles ranging from 0° to 120°. [ABSTRACT FROM AUTHOR]

Published

2024

2. Reconfiguring nucleation for CVD growth of twisted bilayer MoS2 with a wide range of twist angles.

Author

Xu, Manzhang, Ji, Hongjia, Zheng, Lu, Li, Weiwei, Wang, Jing, Wang, Hanxin, Luo, Lei, Lu, Qianbo, Gan, Xuetao, Liu, Zheng, Wang, Xuewen, and Huang, Wei

Subjects

SUPERLATTICES, DISCONTINUOUS precipitation, ELECTRONIC band structure, CONDENSED matter physics, CHEMICAL vapor deposition, ANGLES, BIOELECTRONICS, BILAYER lipid membranes

Abstract

Twisted bilayer (TB) transition metal dichalcogenides (TMDCs) beyond TB-graphene are considered an ideal platform for investigating condensed matter physics, due to the moiré superlattices-related peculiar band structures and distinct electronic properties. The growth of large-area and high-quality TB-TMDCs with wide twist angles would be significant for exploring twist angle-dependent physics and applications, but remains challenging to implement. Here, we propose a reconfiguring nucleation chemical vapor deposition (CVD) strategy for directly synthesizing TB-MoS2 with twist angles from 0° to 120°. The twist angles-dependent Moiré periodicity can be clearly observed, and the interlayer coupling shows a strong relationship to the twist angles. Moreover, the yield of TB-MoS2 in bilayer MoS2 and density of TB-MoS2 are significantly improved to 17.2% and 28.9 pieces/mm2 by tailoring gas flow rate and molar ratio of NaCl to MoO3. The proposed reconfiguring nucleation approach opens an avenue for the precise growth of TB-TMDCs for both fundamental research and practical applications. Twisted bilayers of 2D semiconductors are being intensively investigated due to their emergent physical properties, but their controlled bottom-up synthesis remains challenging. Here, the authors report a confined-space chemical vapour deposition strategy to synthesize MoS2 bilayers with twist angles ranging from 0° to 120°. [ABSTRACT FROM AUTHOR]

Published

2024