Large-Scale Silver Sulfide Nanomesh Membranes with Ultrahigh Flexibility

, , , , , , , & (2022) Large-Scale Silver Sulfide Nanomesh Membranes with Ultrahigh Flexibility. Nano Letters, 22(24), pp. 9883-9890.

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Description

The growth of flexible semiconductor thin films and membranes is highly desirable for the fabrication of next-generation wearable devices. In this work, we have developed a one-step, surface tension-driven method for facile and scalable growth of silver sulfide (Ag2S) membranes with a nanomesh structure. The nanomesh membrane can in principle reach infinite size but only limited by the reactor size, while the thickness is self-limited to ca. 50 nm. In particular, the membrane can be continuously regenerated at the water surface after being transferred for mechanical and electronic tests. The free-standing membrane demonstrates exceptional flexibility and strength, resulting from the nanomesh structure and the intrinsic plasticity of the Ag2S ligaments, as revealed by robust manipulation, nanoindentation tests and a pseudo-in situ tensile test under scanning electron microscope. Bendable electronic resistance-switching devices are fabricated based on the nanomesh membrane.

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ID Code: 237119
Item Type: Contribution to Journal (Journal Article)
Refereed: Yes
ORCID iD:
Li, Weiorcid.org/0000-0001-7835-5360
Meng, Pengorcid.org/0000-0002-4624-2430
Yan, Chengorcid.org/0000-0002-4909-439X
Qi, Dong Chenorcid.org/0000-0001-8466-0257
Xu, Jingsanorcid.org/0000-0003-1172-3864
Additional Information: Acknowledgments: The authors acknowledge the financial support by the Australian Research Council. The faculty of Science and Central Analytical Research Facility (CARF) at QUT are greatly acknowledged for technical assistance. We thank Dr. M. Johnston from the Faculty of Engineering for modelling and 3D printing of the tensile test stage.
Measurements or Duration: 8 pages
Keywords: Flexible nanomesh, In-situ tensile test, Nanoindentation, Nanoscale plasticity, Resistance-switching device
DOI: 10.1021/acs.nanolett.2c03153
ISSN: 1530-6984
Pure ID: 121454534
Divisions: Current > Research Centres > Centre for Materials Science
Current > QUT Faculties and Divisions > Academic Division
Current > QUT Faculties and Divisions > Faculty of Science
Current > Schools > School of Chemistry & Physics
Current > QUT Faculties and Divisions > Faculty of Engineering
Current > Schools > School of Mechanical, Medical & Process Engineering
Funding Information: The authors acknowledge the financial support by the Australian Research Council. The faculty of Science and Central Analytical Research Facility (CARF) at QUT are greatly acknowledged for technical assistance. We thank Dr. M. Johnston from the Faculty of Engineering for modelling and 3D printing of the tensile test stage.
Copyright Owner: 2022 American Chemical Society
Copyright Statement: This work is covered by copyright. Unless the document is being made available under a Creative Commons Licence, you must assume that re-use is limited to personal use and that permission from the copyright owner must be obtained for all other uses. If the document is available under a Creative Commons License (or other specified license) then refer to the Licence for details of permitted re-use. It is a condition of access that users recognise and abide by the legal requirements associated with these rights. If you believe that this work infringes copyright please provide details by email to qut.copyright@qut.edu.au
Deposited On: 23 Jan 2023 03:27
Last Modified: 26 May 2024 19:59

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