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Control Strategies for Solution‐Processed ZTO‐Based Thin‐Film Transistors Tailored Toward Volatile Organic Compound Detection

Miller, Lauren R; Galán-González, Alejandro; Nicholson, Ben; Bowen, Leon; Monier, Guillaume; Borthwick, Robert J; White, Freddie; Saeed, Mana; Thompson, Richard L; Robert-Goumet, Christine; Atkinson, Del; Zeze, Dagou A; Chaudhry, Mujeeb U; Souop, Mekoagne; Bideux, Luc

Control Strategies for Solution‐Processed ZTO‐Based Thin‐Film Transistors Tailored Toward Volatile Organic Compound Detection Thumbnail


Authors

Profile image of Lauren Miller

Lauren Miller lauren.r.miller@durham.ac.uk
Marking Demo & Teaching Support

Alejandro Galán-González

Leon Bowen leon.bowen@durham.ac.uk
Senior Manager (Electron Microscopy)

Guillaume Monier

Profile image of Rob Borthwick

Dr Rob Borthwick robert.j.borthwick@durham.ac.uk
Senior Technician (Mechanical Engineering)

Mana Saeed mana.saeed@durham.ac.uk
PGR Student Doctor of Philosophy

Christine Robert-Goumet

Mekoagne Souop

Luc Bideux



Abstract

A breakthrough in the fabrication of amorphous Zn‐Sn‐O (ZTO)‐based thin‐film transistors (TFTs) is presented for volatile organic compound (VOC) detection. The incorporation of highly abundant materials offers substantial economic and environmental benefits. However, analyses for the design of a multilayer channel are still limited. This work demonstrates that the chemical environment influences ZTO‐based TFTs' carrier transport properties and can be tailored for detecting specific VOCs, ensuring high specificity in diagnosing life‐threatening conditions through simple breath analysis. A low‐cost, high‐throughput, fully solution‐processed ZTO and ZnO multilayering strategy is adopted. The in‐depth compositional and morphological analyses reveal that low surface roughness, excellent Zn and Sn intermixing, high oxygen vacancy (31.2%), and M‐OH bonding (11.4%) contents may account for the outstanding electrical and sensing performance of ZTO‐ZTO TFTs. Notably, these TFTs achieve near‐zero threshold voltage (2.20 V), excellent switching properties (107), and high mobility (10 cm2V−1s−1). This results in high responsivity to alcohol vapors at low‐voltage operation with peak responsivity for methanol (R = 1.08 × 106) over two orders of magnitude greater than acetone. When miniaturized, these devices serve as easy‐to‐operate sensors, capable of detecting VOCs with high specificity in ambient conditions.

Citation

Miller, L. R., Miller, L. R., Galán‐González, A., Galán-González, A., Nicholson, B., Bowen, L., Monier, G., Borthwick, R. J., Borthwick, R. J., White, F., Saeed, M., Thompson, R. L., Thompson, R. L., Robert‐Goumet, C., Robert-Goumet, C., Atkinson, D., Zeze, D. A., Chaudhry, M. U., Souop, M., & Bideux, L. (in press). Control Strategies for Solution‐Processed ZTO‐Based Thin‐Film Transistors Tailored Toward Volatile Organic Compound Detection. Advanced Electronic Materials, Article 2400810. https://doi.org/10.1002/aelm.202400810

Journal Article Type Article
Acceptance Date Jan 16, 2025
Online Publication Date Jan 23, 2025
Deposit Date Jan 22, 2025
Publicly Available Date Jan 23, 2025
Journal Advanced Electronic Materials
Electronic ISSN 2199-160X
Publisher Wiley
Peer Reviewed Peer Reviewed
Article Number 2400810
DOI https://doi.org/10.1002/aelm.202400810
Keywords metal oxide, amorphous, thin‐film transistor, volatile organic compounds, solution‐processed
Public URL https://durham-repository.worktribe.com/output/3345421

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