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Bismuth telluride topological insulator synthesized using liquid metal alloys: test of NO2 selective sensing

Bismuth telluride topological insulator synthesized using liquid metal alloys: test of NO2 selective sensing
Bismuth telluride topological insulator synthesized using liquid metal alloys: test of NO2 selective sensing

Nanostructured topological insulators (TIs), with high surface area and peculiar charge transport, can be advantageous for gas sensing applications. Here interfaces of liquid gallium alloys are used as reaction media to synthesize highly crystalline bismuth telluride (Bi2Te3), which is a well-known TI. The synthesis via these interfaces is self-driven due to the presence of an autogenous interfacial potential on the liquid gallium-indium alloy (EGaIn). Introducing metal-based cations (Bi3+–HTeO2+ in acidic media) into the interfacial Helmholtz zone results in highly crystalline Bi2Te3 platelets. Due to the non-polar surface of EGaIn liquid, the deposited films can be readily exfoliated. The films exhibit unique morphologies of nanostructured platelet-like branches. Sensors fabricated using Bi2Te3 feature selective and sensitive nitrogen dioxide (NO2) physisorption at low operating temperatures. Overall, utilizing liquid metal interfaces as media to drive reactions, which take advantage of their autogenous surface potential, represents a fast and direct protocol that can be further explored to synthesize a variety of functional nanomaterials. Particularly, the approach offers an opportunity for the creation of TIs which are challenging to achieve using traditional potentiostatic methods.

Autogenous potential, Gallium, Liquid metal interface, Liquid-liquid interface, Self-deposition
2352-9407
Mousavi, Maedehsadat
43bca89f-f14f-4c48-95f2-8a3b021945de
Ghasemian, Mohammad B.
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Han, Jialuo
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Wang, Yifang
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Abbasi, Roozbeh
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Yang, Jiong
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Tang, Jianbo
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Idrus-Saidi, Shuhada A.
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Guan, Xinwei
5e6447fc-7bcb-4982-a8ac-fffd085dc3f9
Christoe, Michael J.
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Merhebi, Salma
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Zhang, Chengchen
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Tang, Junma
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Jalili, Rouhollah
cb43aeb5-25fd-48ca-a4d2-be016eea3fef
Daeneke, Torben
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Wu, Tom
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Kalantar-Zadeh, Kourosh
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Mayyas, Mohannad
9f9295c4-deda-4289-9cc8-bba31bce5c99
Mousavi, Maedehsadat
43bca89f-f14f-4c48-95f2-8a3b021945de
Ghasemian, Mohammad B.
10f753c5-c1b6-4537-84a0-9c5ca9dadaf2
Han, Jialuo
56fce4b1-540d-4619-8542-bc61548224ab
Wang, Yifang
e6b9a4e5-a91b-418e-9e14-a877e5fcc32c
Abbasi, Roozbeh
e052784f-2858-4c2d-aff8-2fee6fcd479d
Yang, Jiong
69a8f107-4f74-495f-9944-f15e966ef87c
Tang, Jianbo
87473905-8e35-48a1-a776-88080bb751b9
Idrus-Saidi, Shuhada A.
5b63d1ee-c4a6-4c25-9d56-d1d1c6c1413d
Guan, Xinwei
5e6447fc-7bcb-4982-a8ac-fffd085dc3f9
Christoe, Michael J.
7e6b2bde-aa5a-463d-8d58-b0c87ef563ee
Merhebi, Salma
1d12f9d9-d9b9-4eb6-b328-b9322c4eaada
Zhang, Chengchen
abc47c06-4b99-4aed-be72-463f211e9dfa
Tang, Junma
2c4327a5-96db-427a-ba67-30b9a0907a3d
Jalili, Rouhollah
cb43aeb5-25fd-48ca-a4d2-be016eea3fef
Daeneke, Torben
834c5690-15d3-4006-a9d1-cfdaeaabe507
Wu, Tom
f65413c9-7e81-4252-86bb-e19f8cceea9e
Kalantar-Zadeh, Kourosh
aded6a64-8612-40b7-aae9-233fbae916a6
Mayyas, Mohannad
9f9295c4-deda-4289-9cc8-bba31bce5c99

Mousavi, Maedehsadat, Ghasemian, Mohammad B., Han, Jialuo, Wang, Yifang, Abbasi, Roozbeh, Yang, Jiong, Tang, Jianbo, Idrus-Saidi, Shuhada A., Guan, Xinwei, Christoe, Michael J., Merhebi, Salma, Zhang, Chengchen, Tang, Junma, Jalili, Rouhollah, Daeneke, Torben, Wu, Tom, Kalantar-Zadeh, Kourosh and Mayyas, Mohannad (2021) Bismuth telluride topological insulator synthesized using liquid metal alloys: test of NO2 selective sensing. Applied Materials Today, 22, [100954]. (doi:10.1016/j.apmt.2021.100954).

Record type: Article

Abstract

Nanostructured topological insulators (TIs), with high surface area and peculiar charge transport, can be advantageous for gas sensing applications. Here interfaces of liquid gallium alloys are used as reaction media to synthesize highly crystalline bismuth telluride (Bi2Te3), which is a well-known TI. The synthesis via these interfaces is self-driven due to the presence of an autogenous interfacial potential on the liquid gallium-indium alloy (EGaIn). Introducing metal-based cations (Bi3+–HTeO2+ in acidic media) into the interfacial Helmholtz zone results in highly crystalline Bi2Te3 platelets. Due to the non-polar surface of EGaIn liquid, the deposited films can be readily exfoliated. The films exhibit unique morphologies of nanostructured platelet-like branches. Sensors fabricated using Bi2Te3 feature selective and sensitive nitrogen dioxide (NO2) physisorption at low operating temperatures. Overall, utilizing liquid metal interfaces as media to drive reactions, which take advantage of their autogenous surface potential, represents a fast and direct protocol that can be further explored to synthesize a variety of functional nanomaterials. Particularly, the approach offers an opportunity for the creation of TIs which are challenging to achieve using traditional potentiostatic methods.

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More information

Published date: 29 January 2021
Additional Information: Funding Information: The authors gratefully acknowledge the Australian Research Council (ARC) Laureate Fellowship grant (FL180100053) and ARC Centre of Excellence FLEET (CE170100039) for the financial support in this work. The author also wishes to acknowledge the support and facilities provided by the UNSW Electron Microscope Unit (EMU). The raw and processed data of this work can be shared upon request. Please kindly contact the corresponding authors. Publisher Copyright: © 2021 Elsevier Ltd
Keywords: Autogenous potential, Gallium, Liquid metal interface, Liquid-liquid interface, Self-deposition

Identifiers

Local EPrints ID: 482314
URI: http://eprints.soton.ac.uk/id/eprint/482314
DOI: doi:10.1016/j.apmt.2021.100954
ISSN: 2352-9407
PURE UUID: 8665f4e7-371f-4d75-8d20-b30a0d1929b7
ORCID for Chengchen Zhang: ORCID iD orcid.org/0000-0001-8802-539X

Catalogue record

Date deposited: 26 Sep 2023 16:51
Last modified: 18 Mar 2024 04:15

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Contributors

Author: Maedehsadat Mousavi
Author: Mohammad B. Ghasemian
Author: Jialuo Han
Author: Yifang Wang
Author: Roozbeh Abbasi
Author: Jiong Yang
Author: Jianbo Tang
Author: Shuhada A. Idrus-Saidi
Author: Xinwei Guan
Author: Michael J. Christoe
Author: Salma Merhebi
Author: Chengchen Zhang ORCID iD
Author: Junma Tang
Author: Rouhollah Jalili
Author: Torben Daeneke
Author: Tom Wu
Author: Kourosh Kalantar-Zadeh
Author: Mohannad Mayyas

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