Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing

Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing

© 2016 Elsevier B.V. All rights reserved. In this work, Zn-In-O nanoparticles with different Zn metallic contents (100·Zn/(Zn + In)) were produced by one-step flame spray pyrolysis technique and systematically characterized for NO2sensing. Structural characterizations by x-ray diffraction, transmiss...

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Main Authors: T. Samerjai, D. Channei, C. Khanta, K. Inyawilert, C. Liewhiran, A. Wisitsoraat, D. Phokharatkul, S. Phanichphant
Format: Journal
Published: 2018
Subjects:
Engineering
Materials Science
Online Access:https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84964987461&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/55733
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-557332018-09-05T03:04:33Z Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing T. Samerjai D. Channei C. Khanta K. Inyawilert C. Liewhiran A. Wisitsoraat D. Phokharatkul S. Phanichphant Engineering Materials Science © 2016 Elsevier B.V. All rights reserved. In this work, Zn-In-O nanoparticles with different Zn metallic contents (100·Zn/(Zn + In)) were produced by one-step flame spray pyrolysis technique and systematically characterized for NO2sensing. Structural characterizations by x-ray diffraction, transmission and scanning electron microscopy indicated that Zn and In form solid-solution oxide with smaller particle size and lower crystallinity compared with undoped ZnO and In2O3ones. In addition, energy-dispersive and X-ray photoemission spectroscopic analyses revealed that materials prepared with Zn content of 25% and 33% were In-rich oxides while those prepared with Zn contents of 40% and 50% were actually Zn-rich oxides. From gas-sensing measurement, only Zn-In-O sensors with the 50% input Zn content showed improved NO2response while other Zn-In-O sensors displayed inferior performances compared with undoped In2O3sensors. The roles of Zn content on NO2-sensing mechanisms of Zn-In-O sensor were explained based on particle/grain size and doping effects of solid-solution oxide. The Zn-In-O oxide with 50% input Zn content exhibited the optimal sensor response of 1476 to 5 ppm NO2at 250 °C. In addition, it still had good responses of 17 to low NO2concentrations of 0.125 ppm and good selectivity against NO, H2, H2S and CO. Therefore, the flame-made Zn-In-O sensor is another promising candidate for sensitive and selective NO2detections. 2018-09-05T03:00:24Z 2018-09-05T03:00:24Z 2016-09-25 Journal 09258388 2-s2.0-84964987461 10.1016/j.jallcom.2016.04.160 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84964987461&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/55733
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Engineering
Materials Science
spellingShingle Engineering
Materials Science
T. Samerjai
D. Channei
C. Khanta
K. Inyawilert
C. Liewhiran
A. Wisitsoraat
D. Phokharatkul
S. Phanichphant
Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
description © 2016 Elsevier B.V. All rights reserved. In this work, Zn-In-O nanoparticles with different Zn metallic contents (100·Zn/(Zn + In)) were produced by one-step flame spray pyrolysis technique and systematically characterized for NO2sensing. Structural characterizations by x-ray diffraction, transmission and scanning electron microscopy indicated that Zn and In form solid-solution oxide with smaller particle size and lower crystallinity compared with undoped ZnO and In2O3ones. In addition, energy-dispersive and X-ray photoemission spectroscopic analyses revealed that materials prepared with Zn content of 25% and 33% were In-rich oxides while those prepared with Zn contents of 40% and 50% were actually Zn-rich oxides. From gas-sensing measurement, only Zn-In-O sensors with the 50% input Zn content showed improved NO2response while other Zn-In-O sensors displayed inferior performances compared with undoped In2O3sensors. The roles of Zn content on NO2-sensing mechanisms of Zn-In-O sensor were explained based on particle/grain size and doping effects of solid-solution oxide. The Zn-In-O oxide with 50% input Zn content exhibited the optimal sensor response of 1476 to 5 ppm NO2at 250 °C. In addition, it still had good responses of 17 to low NO2concentrations of 0.125 ppm and good selectivity against NO, H2, H2S and CO. Therefore, the flame-made Zn-In-O sensor is another promising candidate for sensitive and selective NO2detections.
format Journal
author T. Samerjai
D. Channei
C. Khanta
K. Inyawilert
C. Liewhiran
A. Wisitsoraat
D. Phokharatkul
S. Phanichphant
author_facet T. Samerjai
D. Channei
C. Khanta
K. Inyawilert
C. Liewhiran
A. Wisitsoraat
D. Phokharatkul
S. Phanichphant
author_sort T. Samerjai
title Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
title_short Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
title_full Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
title_fullStr Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
title_full_unstemmed Flame-spray-made Zn-In-O alloyed nanoparticles for NO<inf>2</inf>gas sensing
title_sort flame-spray-made zn-in-o alloyed nanoparticles for no<inf>2</inf>gas sensing
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84964987461&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/55733
_version_ 1681424560569712640

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