The Extremely Enhanced Photocurrent Response in Topological Insulator Nanosheets with High Conductance

Shiu Ming Huang; Lin Jie Lin; You Jhih Yan; Shih Hsun Yu; Mitch M.C. Chou; Ho Feng Hsieh; Chin Jung Ho; Ruei San Chen

doi:10.1186/s11671-018-2758-0

The Extremely Enhanced Photocurrent Response in Topological Insulator Nanosheets with High Conductance

Shiu Ming Huang
, Lin Jie Lin
, You Jhih Yan
, Shih Hsun Yu
, Mitch M.C. Chou
, Ho Feng Hsieh
, Chin Jung Ho
, Ruei San Chen

Program on Key Materials

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

The photocurrent was performed in topological insulator nanosheets with different conductances. The higher photocurrent is observed in the nanosheet with higher conductance. The responsivity is proportional to the nanosheet conductance over two orders. The responsivity is independent of the light power intensity in vacuum, but responsivity drastically decreases at low power intensity in air. The ratio of the responsivity in air to that in vacuum is negatively proportional to the the inverse of the light power intensity. These behaviors are understood as the statistical photocurrent in a system with blocked molecules. The time constant decreases as the thickness increases. A longer time constant is observed in lower atmosphere pressure.

Original language	English
Article number	371
Journal	Nanoscale Research Letters
Volume	13
DOIs	https://doi.org/10.1186/s11671-018-2758-0
Publication status	Published - 2018

All Science Journal Classification (ASJC) codes

General Materials Science
Condensed Matter Physics

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title = "The Extremely Enhanced Photocurrent Response in Topological Insulator Nanosheets with High Conductance",

abstract = "The photocurrent was performed in topological insulator nanosheets with different conductances. The higher photocurrent is observed in the nanosheet with higher conductance. The responsivity is proportional to the nanosheet conductance over two orders. The responsivity is independent of the light power intensity in vacuum, but responsivity drastically decreases at low power intensity in air. The ratio of the responsivity in air to that in vacuum is negatively proportional to the the inverse of the light power intensity. These behaviors are understood as the statistical photocurrent in a system with blocked molecules. The time constant decreases as the thickness increases. A longer time constant is observed in lower atmosphere pressure.",

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AU - Huang, Shiu Ming

AU - Lin, Lin Jie

AU - Yan, You Jhih

AU - Yu, Shih Hsun

AU - Chou, Mitch M.C.

AU - Hsieh, Ho Feng

AU - Ho, Chin Jung

AU - Chen, Ruei San

PY - 2018

Y1 - 2018

N2 - The photocurrent was performed in topological insulator nanosheets with different conductances. The higher photocurrent is observed in the nanosheet with higher conductance. The responsivity is proportional to the nanosheet conductance over two orders. The responsivity is independent of the light power intensity in vacuum, but responsivity drastically decreases at low power intensity in air. The ratio of the responsivity in air to that in vacuum is negatively proportional to the the inverse of the light power intensity. These behaviors are understood as the statistical photocurrent in a system with blocked molecules. The time constant decreases as the thickness increases. A longer time constant is observed in lower atmosphere pressure.

AB - The photocurrent was performed in topological insulator nanosheets with different conductances. The higher photocurrent is observed in the nanosheet with higher conductance. The responsivity is proportional to the nanosheet conductance over two orders. The responsivity is independent of the light power intensity in vacuum, but responsivity drastically decreases at low power intensity in air. The ratio of the responsivity in air to that in vacuum is negatively proportional to the the inverse of the light power intensity. These behaviors are understood as the statistical photocurrent in a system with blocked molecules. The time constant decreases as the thickness increases. A longer time constant is observed in lower atmosphere pressure.

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ER -

The Extremely Enhanced Photocurrent Response in Topological Insulator Nanosheets with High Conductance

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