Synthesis-in-place of V2O5 nanobelts for wide range humidity detection

Resistive type humidity sensors offer advantages in simplicity, low cost, compact size, and remote operation. Due to the benefits, they have great potential for use in a variety of environments and future applications, including the Internet of Everything (IoE). However, resistive humidity sensors h...

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Published inSensors and actuators. B, Chemical Vol. 423; p. 136711
Main Authors Cho, Sungjin, Lim, Si Heon, Oh, Jaeyeon, Ju, Tae-Seong, Yang, Seungmo, Kim, Hyun Ho, Kim, Yeonhoo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.01.2025
Subjects
Chemoresistive
Humidity sensor
Nanostructures
Physical vapor transport
Vanadium pentoxide
Humidity sensor
Vanadium pentoxide
Nanostructures
Physical vapor transport
Chemoresistive
Online AccessGet full text
ISSN0925-4005
DOI10.1016/j.snb.2024.136711

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Abstract Resistive type humidity sensors offer advantages in simplicity, low cost, compact size, and remote operation. Due to the benefits, they have great potential for use in a variety of environments and future applications, including the Internet of Everything (IoE). However, resistive humidity sensors have limitations in detecting extreme humidity levels below 10 % or above 90 % relative humidity (RH) and are also vulnerable to high temperatures, which hinders their use in harsh environments applications. For broader applications, humidity sensors with reliable performance across the full range of humidity levels and high stability at elevated temperatures need to be developed. Here, we report high performance resistive humidity sensors based on V2O5 nanobelts operating at high temperatures. The V2O5 nanobelts are directly deposited between Pt electrodes by O2-assisted physical vapor transport (PVT) method. The V2O5 nanobelt humidity sensor exhibits reliable humidity sensing properties over a wide range from 1 % to 100 % RH. Furthermore, long-term stability and reproducibility of V2O5 nanobelts are demonstrated through 25 consecutive humid air pulses and measurements obtained after 4 months of storage. The high performance of the V2O5 nanobelt humidity sensor is advantageous for practical use in applications ranging from IoE environments to harsh industrial conditions. •Synthesis-in-place V2O5 nanobelts were fabricated by physical vapor transport method.•The V2O5 nanobelt sensor shows high sensitivity to low humidity range from 1 % to 10 %.•The sensor demonstrates excellent long-term stability over 4 months.•The synthesis-in-place sensor exhibits high stability at elevated temperatures
AbstractList Resistive type humidity sensors offer advantages in simplicity, low cost, compact size, and remote operation. Due to the benefits, they have great potential for use in a variety of environments and future applications, including the Internet of Everything (IoE). However, resistive humidity sensors have limitations in detecting extreme humidity levels below 10 % or above 90 % relative humidity (RH) and are also vulnerable to high temperatures, which hinders their use in harsh environments applications. For broader applications, humidity sensors with reliable performance across the full range of humidity levels and high stability at elevated temperatures need to be developed. Here, we report high performance resistive humidity sensors based on V2O5 nanobelts operating at high temperatures. The V2O5 nanobelts are directly deposited between Pt electrodes by O2-assisted physical vapor transport (PVT) method. The V2O5 nanobelt humidity sensor exhibits reliable humidity sensing properties over a wide range from 1 % to 100 % RH. Furthermore, long-term stability and reproducibility of V2O5 nanobelts are demonstrated through 25 consecutive humid air pulses and measurements obtained after 4 months of storage. The high performance of the V2O5 nanobelt humidity sensor is advantageous for practical use in applications ranging from IoE environments to harsh industrial conditions. •Synthesis-in-place V2O5 nanobelts were fabricated by physical vapor transport method.•The V2O5 nanobelt sensor shows high sensitivity to low humidity range from 1 % to 10 %.•The sensor demonstrates excellent long-term stability over 4 months.•The synthesis-in-place sensor exhibits high stability at elevated temperatures
ArticleNumber 136711
Author Oh, Jaeyeon
Yang, Seungmo
Kim, Yeonhoo
Cho, Sungjin
Ju, Tae-Seong
Lim, Si Heon
Kim, Hyun Ho
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Keywords Humidity sensor
Vanadium pentoxide
Nanostructures
Physical vapor transport
Chemoresistive
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Snippet Resistive type humidity sensors offer advantages in simplicity, low cost, compact size, and remote operation. Due to the benefits, they have great potential...
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SubjectTerms Chemoresistive
Humidity sensor
Nanostructures
Physical vapor transport
Vanadium pentoxide
Title Synthesis-in-place of V2O5 nanobelts for wide range humidity detection
URI https://dx.doi.org/10.1016/j.snb.2024.136711
Volume 423
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