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Graphene-protected nickel hollow fibre membrane and its application in the production of high-performance catalysts

Graphene-protected nickel hollow fibre membrane and its application in the production of high-performance catalysts
Graphene-protected nickel hollow fibre membrane and its application in the production of high-performance catalysts

Graphene as a protective coating has raised many interests. This ultra-thin material is chemically inert, and it is impermeable to gases and liquids, therefore it can act as a protective coating to enhance the lifespan and chemical resistance of metallic membranes. In this study, graphene protected nickel hollow fibre (G-Ni-HF) membrane was fabricated using the phase-inversion and facile single-stage sintering-chemical vapour deposition (CVD) process. The non-protected nickel hollow fibre membrane dissolved in nitric acid within a few hours, whereas the G-Ni-HF membrane remained intact. The as-prepared G-Ni-HF membrane featuring well-controlled pore structure, good chemical stability and mechanical robustness can be used in a variety of applications that involve harsh conditions. Here, we demonstrated its use in membrane emulsification to prepare TiO2 microspheres, where a highly acidic condition is essential. The microspheres prepared using G-Ni-HF membrane possess a hierarchical asymmetric egg-white structure that is distinct from the symmetric microspheres obtained by normal emulsification method. The asymmetric TiO2 microspheres also exhibit substantially improved catalytic activity to CO oxidation after impregnating with a palladium catalyst.

Chemical inertness, Graphene, Membrane emulsification, Nickel hollow fibre, TiO catalyst
0376-7388
Chi, Yunsi
ec0a924a-41ba-4379-ad88-cf8b103a856d
Li, Tao
dc913e14-8fa6-4956-bacb-8d06eaf06ed2
Chong, Jeng Yi
2f9ead94-86f2-4e20-9e67-75f10759555b
Wang, Bo
c7e48a2e-8790-4e1f-9740-5b50dd713030
Li, Kang
0f88a8e1-2691-46af-acb0-7176c79f5aa7
Chi, Yunsi
ec0a924a-41ba-4379-ad88-cf8b103a856d
Li, Tao
dc913e14-8fa6-4956-bacb-8d06eaf06ed2
Chong, Jeng Yi
2f9ead94-86f2-4e20-9e67-75f10759555b
Wang, Bo
c7e48a2e-8790-4e1f-9740-5b50dd713030
Li, Kang
0f88a8e1-2691-46af-acb0-7176c79f5aa7

Chi, Yunsi, Li, Tao, Chong, Jeng Yi, Wang, Bo and Li, Kang (2019) Graphene-protected nickel hollow fibre membrane and its application in the production of high-performance catalysts. Journal of Membrane Science, 597, [117617]. (doi:10.1016/j.memsci.2019.117617).

Record type: Article

Abstract

Graphene as a protective coating has raised many interests. This ultra-thin material is chemically inert, and it is impermeable to gases and liquids, therefore it can act as a protective coating to enhance the lifespan and chemical resistance of metallic membranes. In this study, graphene protected nickel hollow fibre (G-Ni-HF) membrane was fabricated using the phase-inversion and facile single-stage sintering-chemical vapour deposition (CVD) process. The non-protected nickel hollow fibre membrane dissolved in nitric acid within a few hours, whereas the G-Ni-HF membrane remained intact. The as-prepared G-Ni-HF membrane featuring well-controlled pore structure, good chemical stability and mechanical robustness can be used in a variety of applications that involve harsh conditions. Here, we demonstrated its use in membrane emulsification to prepare TiO2 microspheres, where a highly acidic condition is essential. The microspheres prepared using G-Ni-HF membrane possess a hierarchical asymmetric egg-white structure that is distinct from the symmetric microspheres obtained by normal emulsification method. The asymmetric TiO2 microspheres also exhibit substantially improved catalytic activity to CO oxidation after impregnating with a palladium catalyst.

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More information

Published date: 28 October 2019
Additional Information: Funding Information: The authors gratefully acknowledge the research funding provided by EPSRC in the United Kingdom (Grant no. EP/M022250/1 ). Appendix A Funding Information: The authors gratefully acknowledge the research funding provided by EPSRC in the United Kingdom (Grant no. EP/M022250/1). Publisher Copyright: © 2019
Keywords: Chemical inertness, Graphene, Membrane emulsification, Nickel hollow fibre, TiO catalyst

Identifiers

Local EPrints ID: 486380
URI: http://eprints.soton.ac.uk/id/eprint/486380
DOI: doi:10.1016/j.memsci.2019.117617
ISSN: 0376-7388
PURE UUID: 073c4aca-d082-4eec-9bf3-5d4c142759d6
ORCID for Jeng Yi Chong: ORCID iD orcid.org/0000-0002-0593-6313

Catalogue record

Date deposited: 18 Jan 2024 19:26
Last modified: 12 Nov 2024 03:15

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Contributors

Author: Yunsi Chi
Author: Tao Li
Author: Jeng Yi Chong ORCID iD
Author: Bo Wang
Author: Kang Li

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