Issue 13, 2013

Single ZnO nanotetrapod-based sensors for monitoring localized UV irradiation

Abstract

Single ZnO nanotetrapod-based sensors for monitoring localized UV irradiation were constructed with ohmic and Schottky contact characteristics. Localized UV irradiation at the third leg of the tetrapod was monitored by measuring the sensor's current response. Measurements of IV performances and time-resolved current were conducted. The results demonstrate that localized UV irradiation can be detected in real time as electrical transport properties can be modulated by localized UV irradiation, and the higher the UV light power density gets, the larger the current response becomes, which is observed to be completely repeatable and reversible. Additionally, Schottky-contact type sensors clearly show a greater current response than ohmic-contact-type sensors, which further proved that Schottky-contact-type sensors are a better choice for detection in an irradiation environment. Two possible explanations are given for the phenomenon, including an electron transfer effect and a surface/interface effect on the band structure. The as-constructed sensors exhibit different sensitivities towards irradiation with various power densities, indicating that ZnO nanotetrapod-based sensors can be a promising candidate for detection in many areas including electron irradiation detection, ultraviolet irradiation monitoring, strain sensing, and complicated microenvironment observations such as biological cell inspection.

Graphical abstract: Single ZnO nanotetrapod-based sensors for monitoring localized UV irradiation

Article information

Article type
Paper
Submitted
22 Dec 2012
Accepted
22 Apr 2013
First published
24 Apr 2013

Nanoscale, 2013,5, 5981-5985

Single ZnO nanotetrapod-based sensors for monitoring localized UV irradiation

W. Wang, J. Qi, Q. Wang, Y. Huang, Q. Liao and Y. Zhang, Nanoscale, 2013, 5, 5981 DOI: 10.1039/C3NR34247F

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