Fabrication of High-Quality In2Se3 Nanowire Arrays toward High-Performance Visible-Light Photodetectors

Zhai, Tianyou; Fang, Xiaosheng; Liao, Meiyong; Xu, Xijin; Li, Liang; Liu, Baodan; Koide, Yasuo; Ma, Ying; Yao, Jiannian; Bando, Yoshio; Golberg, Dmitri

doi:10.1021/nn9012466

Author(s)

Zhai, Tianyou

Fang, Xiaosheng

Liao, Meiyong

Xu, Xijin

Li, Liang

Liu, Baodan

Koide, Yasuo

Ma, Ying

Yao, Jiannian

Bando, Yoshio

Golberg, Dmitri

Griffith University Author(s)

Xu, Xijin

Year published

2010

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Abstract

The synthesis of high-quality In2Se3 nanowire arrays via thermal evaporation method and the photoconductive characteristics of In2Se3 individual nanowires are first investigated. The electrical characterization of a single In2Se3 nanowire verifies an intrinsic n-type semiconductor behavior. These single-crystalline In2Se3 nanowires are then assembled in visible-light sensors which demonstrate a fast, reversible, and stable response. The high photosensitivity and quick photoresponse are attributed to the superior single-crystal quality and large surface-to-volume ratio resulting in fewer recombination barriers in nanostructures. ...
View more >The synthesis of high-quality In2Se3 nanowire arrays via thermal evaporation method and the photoconductive characteristics of In2Se3 individual nanowires are first investigated. The electrical characterization of a single In2Se3 nanowire verifies an intrinsic n-type semiconductor behavior. These single-crystalline In2Se3 nanowires are then assembled in visible-light sensors which demonstrate a fast, reversible, and stable response. The high photosensitivity and quick photoresponse are attributed to the superior single-crystal quality and large surface-to-volume ratio resulting in fewer recombination barriers in nanostructures. These excellent performances clearly demonstrate the possibility of using In2Se3 nanowires in next-generation sensors and detectors for commercial, military, and space applications.
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Journal Title

ACS Nano

Volume

Issue

DOI

https://doi.org/10.1021/nn9012466

Copyright Statement

Self-archiving of the author-manuscript version is not yet supported by this journal. Please refer to the journal link for access to the definitive, published version or contact the author[s] for more information.

Subject

Condensed Matter Physics not elsewhere classified

Condensed Matter Characterisation Technique Development

Publication URI

http://hdl.handle.net/10072/40172

Collection

Journal articles