Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing

Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing

© 2014 American Chemical Society. The influence of deep level surface defects on electrical and gas sensing properties of ZnO nanorods NH3(g) sensors was studied. ZnO nanorods 50-60 nm in diameter were synthesized via low-temperature hydrothermal growth at 90°C on sapphire substrates. The as-grown n...

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Main Authors: Suranan Anantachaisilp, Siwaporn Meejoo Smith, Cuong Ton-That, Tanakorn Osotchan, Anthony R. Moon, Matthew R. Phillips
Other Authors: University of Technology Sydney
Format: Article
Published: 2018
Subjects:
Chemistry
Energy
Materials Science
Online Access:https://repository.li.mahidol.ac.th/handle/123456789/33655
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spelling th-mahidol.336552018-11-09T09:29:41Z Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing Suranan Anantachaisilp Siwaporn Meejoo Smith Cuong Ton-That Tanakorn Osotchan Anthony R. Moon Matthew R. Phillips University of Technology Sydney Mahidol University Chemistry Energy Materials Science © 2014 American Chemical Society. The influence of deep level surface defects on electrical and gas sensing properties of ZnO nanorods NH3(g) sensors was studied. ZnO nanorods 50-60 nm in diameter were synthesized via low-temperature hydrothermal growth at 90°C on sapphire substrates. The as-grown nanorods exhibited a cathodoluminescence (CL) peak centered at 1.90 eV (YL), attributed to LiZndeep acceptors or O interstitials. Subsequent annealing in O2at 1 atm and Zn vapor at 650°C produced broad CL peaks centered at 1.70 eV (RL) and 2.44 eV (GL), respectively. The RL and GL have been ascribed to acceptor-like VZnand donor-like VOrelated centers, respectively. Electrical and gas sensing measurements established that the NH3gas response sensitivity was 22.6 for O2anneal (RL), 1.4 for Zn vapor anneal (GL), and 4.1 for the as-grown (YL) samples. Additionally, treatment in H-plasma quenched the RL and inverted the NH3electrical response due to the incorporation of H donors. Changes in the gas sensing response are explained by a shift in the position of the ZnO Fermi level relative to the chemical potential of NH3gas due to the creation of near surface donor or acceptors. These data confirm that ZnO nanorods arrays can be tailored to detect specific gas species. (Chemical Equation Presented). 2018-11-09T02:07:37Z 2018-11-09T02:07:37Z 2014-01-01 Article Journal of Physical Chemistry C. Vol.118, No.46 (2014), 27150-27156 10.1021/jp5085857 19327455 19327447 2-s2.0-84914695140 https://repository.li.mahidol.ac.th/handle/123456789/33655 Mahidol University SCOPUS https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84914695140&origin=inward
institution Mahidol University
building Mahidol University Library
continent Asia
country Thailand
Thailand
content_provider Mahidol University Library
collection Mahidol University Institutional Repository
topic Chemistry
Energy
Materials Science
spellingShingle Chemistry
Energy
Materials Science
Suranan Anantachaisilp
Siwaporn Meejoo Smith
Cuong Ton-That
Tanakorn Osotchan
Anthony R. Moon
Matthew R. Phillips
Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
description © 2014 American Chemical Society. The influence of deep level surface defects on electrical and gas sensing properties of ZnO nanorods NH3(g) sensors was studied. ZnO nanorods 50-60 nm in diameter were synthesized via low-temperature hydrothermal growth at 90°C on sapphire substrates. The as-grown nanorods exhibited a cathodoluminescence (CL) peak centered at 1.90 eV (YL), attributed to LiZndeep acceptors or O interstitials. Subsequent annealing in O2at 1 atm and Zn vapor at 650°C produced broad CL peaks centered at 1.70 eV (RL) and 2.44 eV (GL), respectively. The RL and GL have been ascribed to acceptor-like VZnand donor-like VOrelated centers, respectively. Electrical and gas sensing measurements established that the NH3gas response sensitivity was 22.6 for O2anneal (RL), 1.4 for Zn vapor anneal (GL), and 4.1 for the as-grown (YL) samples. Additionally, treatment in H-plasma quenched the RL and inverted the NH3electrical response due to the incorporation of H donors. Changes in the gas sensing response are explained by a shift in the position of the ZnO Fermi level relative to the chemical potential of NH3gas due to the creation of near surface donor or acceptors. These data confirm that ZnO nanorods arrays can be tailored to detect specific gas species. (Chemical Equation Presented).
author2 University of Technology Sydney
author_facet University of Technology Sydney
Suranan Anantachaisilp
Siwaporn Meejoo Smith
Cuong Ton-That
Tanakorn Osotchan
Anthony R. Moon
Matthew R. Phillips
format Article
author Suranan Anantachaisilp
Siwaporn Meejoo Smith
Cuong Ton-That
Tanakorn Osotchan
Anthony R. Moon
Matthew R. Phillips
author_sort Suranan Anantachaisilp
title Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
title_short Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
title_full Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
title_fullStr Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
title_full_unstemmed Tailoring deep level surface defects in ZnO nanorods for high sensitivity ammonia gas sensing
title_sort tailoring deep level surface defects in zno nanorods for high sensitivity ammonia gas sensing
publishDate 2018
url https://repository.li.mahidol.ac.th/handle/123456789/33655
_version_ 1763496518014205952

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