Optically Activated 3D Thin‐Shell TiO2 for Super‐Sensitive Chemoresistive Responses: Toward Visible Light Activation. Issue 3 (3rd December 2020)

Record Type:: Journal Article
Title:: Optically Activated 3D Thin‐Shell TiO2 for Super‐Sensitive Chemoresistive Responses: Toward Visible Light Activation. Issue 3 (3rd December 2020)
Main Title:: Optically Activated 3D Thin‐Shell TiO2 for Super‐Sensitive Chemoresistive Responses: Toward Visible Light Activation
Authors:: Cho, Donghwi
Suh, Jun Min
Nam, Sang‐Hyeon
Park, Seo Yun
Park, Minsu
Lee, Tae Hyung
Choi, Kyoung Soon
Lee, Jinho
Ahn, Changui
Jang, Ho Won
Shim, Young‐Seok
Jeon, Seokwoo
Abstract:: Abstract: One of the well‐known strategies for achieving high‐performance light‐activated gas sensors is to design a nanostructure for effective surface responses with its geometric advances. However, no study has gone beyond the benefits of the large surface area and provided fundamental strategies to offer a rational structure for increasing their optical and chemical performances. Here, a new class of UV‐activated sensing nanoarchitecture made of highly periodic 3D TiO2, which facilitates 55 times enhanced light absorption by confining the incident light in the nanostructure, is prepared as an active gas channel. The key parameters, such as the total 3D TiO2 film and thin‐shell thicknesses, are precisely optimized by finite element analysis. Collectively, this fundamental design leads to ultrahigh chemoresistive response to NO2 with a theoretical detection limit of ≈200 ppt. The demonstration of high responses with visible light illumination proposes a future perspective for light‐activated gas sensors based on semiconducting oxides. Abstract : The high‐performance light‐activated NO2 gas sensors using 3D TiO2 nanostructures are achieved by the unique light harvesting properties of the nanoporous structures. The light scattering effects from optical maze‐like nanostructures and numerous intermediate energy states from atomic layer deposition of the film electronically activate 3D TiO2 and enhance its gas sensing performance under UV illumination.
Is Part Of:: Advanced science. Volume 8:Issue 3(2021)
Journal:: Advanced science
Issue:: Volume 8:Issue 3(2021)
Issue Display:: Volume 8, Issue 3 (2021)
Year:: 2021
Volume:: 8
Issue:: 3
Issue Sort Value:: 2021-0008-0003-0000
Page Start:: n/a
Page End:: n/a
Publication Date:: 2020-12-03
Subjects:: gas sensors -- light scattering -- 3D nanostructures -- room temperature -- titanium dioxide
Science -- Periodicals
505
Journal URLs:: http://onlinelibrary.wiley.com/journal/10.1002/(ISSN)2198-3844 ↗
http://onlinelibrary.wiley.com/ ↗
DOI:: 10.1002/advs.202001883 ↗
Languages:: English
ISSNs:: 2198-3844
Deposit Type:: Legaldeposit
View Content:: Available online (eLD content is only available in our Reading Rooms) ↗
Physical Locations:: British Library DSC - BLDSS-3PM
British Library HMNTS - ELD Digital store
Ingest File:: 15821.xml