NO 2 gas sensing performance enhancement based on reduced graphene oxide decorated V 2 O 5 thin films

Here, we demonstrate improved NO gas sensing properties based on reduced graphene oxide (rGO) decorated V O thin film. Excluding the DC sputtering grown V O thin film, rGO was spread over V O thin film by the drop cast method. The formation of several p-n heterojunctions was greatly affected by the...

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Published in:Nanotechnology 2019-05, Vol.30 (22), p.224001
Main Authors: Bhati, Vijendra Singh, Sheela, D, Roul, Basanta, Raliya, Ramesh, Biswas, Pratim, Kumar, Manish, Roy, M S, Nanda, K K, Krupanidhi, S B, Kumar, Mahesh
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cited_by cdi_FETCH-LOGICAL-c1115-ad592b32910f75aa93055c02a42b9f5fed913ec715b140aac353b5f9704dbfc63
cites cdi_FETCH-LOGICAL-c1115-ad592b32910f75aa93055c02a42b9f5fed913ec715b140aac353b5f9704dbfc63
container_end_page
container_issue 22
container_start_page 224001
container_title Nanotechnology
container_volume 30
creator Bhati, Vijendra Singh
Sheela, D
Roul, Basanta
Raliya, Ramesh
Biswas, Pratim
Kumar, Manish
Roy, M S
Nanda, K K
Krupanidhi, S B
Kumar, Mahesh
description Here, we demonstrate improved NO gas sensing properties based on reduced graphene oxide (rGO) decorated V O thin film. Excluding the DC sputtering grown V O thin film, rGO was spread over V O thin film by the drop cast method. The formation of several p-n heterojunctions was greatly affected by the current-voltage relation of the rGO-decorated V O thin film due to the p-type and n-type nature of rGO and V O , respectively. Initially with rGO decoration on V O thin film, current decreased in comparison to the pristine V O thin film, whereas depositing rGO film on a glass substrate drastically increased current. Among all sensors, only the rGO-decorated V O sensor revealed a maximum NO gas sensing response for 100 ppm at 150 °C, and it achieved an approximately 61% higher response than the V O sensor. The elaborate mechanism for an extremely high sensing response is attributed to the formation and modulation of p-n heterojunctions at the interface of rGO and V O . In addition, the presence of active sites like oxygenous functional groups on the rGO surface enhanced the sensing response. On that account, sensors based on rGO-decorated V O thin film are highly suitable for the purpose of NO gas sensing. They enable the timely detection of the gas, further protecting the ecosystem from its harmful effects.
doi_str_mv 10.1088/1361-6528/ab0321
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title NO 2 gas sensing performance enhancement based on reduced graphene oxide decorated V 2 O 5 thin films
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