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Confined van der Waals Epitaxial Growth of Two-Dimensional Large Single-Crystal In2Se3 for Flexible Broadband Photodetectors
Author(s) -
Lei Tang,
Changjiu Teng,
Yuting Luo,
Usman Khan,
Haiyang Pan,
Zhengyang Cai,
Yüe Zhao,
Bilu Liu,
Huhu Cheng
Publication year - 2019
Publication title -
research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.8
H-Index - 16
ISSN - 2639-5274
DOI - 10.1155/2019/2763704
Subject(s) - nucleation , materials science , substrate (aquarium) , chemical vapor deposition , crystal (programming language) , van der waals force , quantum efficiency , epitaxy , crystallinity , photodetector , grain boundary , optoelectronics , nanotechnology , chemistry , composite material , physics , layer (electronics) , thermodynamics , oceanography , organic chemistry , microstructure , molecule , computer science , programming language , geology
The controllable growth of two-dimensional (2D) semiconductors with large domain sizes and high quality is much needed in order to reduce the detrimental effect of grain boundaries on device performance but has proven to be challenging. Here, we analyze the precursor concentration on the substrate surface which significantly influences nucleation density in a vapor deposition growth process and design a confined micro-reactor to grow 2D In 2 Se 3 with large domain sizes and high quality. The uniqueness of this confined micro-reactor is that its size is ~10 2 -10 3 times smaller than that of a conventional reactor. Such a remarkably small reactor causes a very low precursor concentration on the substrate surface, which reduces nucleation density and leads to the growth of 2D In 2 Se 3 grains with sizes larger than 200 μ m. Our experimental results show large domain sizes of the 2D In 2 Se 3 with high crystallinity. The flexible broadband photodetectors based on the as-grown In 2 Se 3 show rise and decay times of 140 ms and 25 ms, efficient response (5.6 A/W), excellent detectivity (7×10 10 Jones), high external quantum efficiency (251%), good flexibility, and high stability. This study, in principle, provides an effective strategy for the controllable growth of high quality 2D materials with few grain boundaries.

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