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Post-transition metal/polymer composites for the separation and sensing of alkali metal ions

Post-transition metal/polymer composites for the separation and sensing of alkali metal ions
Post-transition metal/polymer composites for the separation and sensing of alkali metal ions

The separation and sensing of alkali metal ions from aqueous lithium resources is of great importance for building future renewable and lithium-based energy storage technologies. As such, interest arises for the development of functional composites selective to ionic lithium (Li+) over sodium (Na+) and potassium (K+) that allows for a range of low carbon-footprint sensing and recovery processes. Here, selective separation of Li+from aqueous mixtures of Na+and K+ions using polyvinyl alcohol/maleic acid composites was enhanced by the inclusion as nano-additives of post-transition metals gallium (Ga) and indium (In), together with their alloys and oxidized species, in the composite casting process. The co-addition of Ga and In resulted in the spontaneous formation of Ga oxides and hydroxides while In remained in the metallic state. This Ga-In composite was stable in aqueous solutions containing a high concentration (0.1 M) of mixed alkali metal ions over 5 days and achieved exceptionally high selectivities of Li+over Na+(3.8 ± 0.1) and K+(7.1 ± 0.1). Results from an electrochemical sensing platform technique revealed that Li+selectivity was in the same order as the diffusion rates. This work demonstrated that the low-melting-point post-transition metal alloy enables a one-step low energy fabrication of selective polymeric composites with diverse applications for energy, sensing and separation industries. The work has implications for the efficient manufacture of renewable and lithium-based energy storage technologies.

2050-7488
19854-19864
Merhebi, Salma
1d12f9d9-d9b9-4eb6-b328-b9322c4eaada
Mohammad, Munirah
23b47537-1883-4c4c-8f31-e87abe9b444b
Mayyas, Mohannad
9f9295c4-deda-4289-9cc8-bba31bce5c99
Abbasi, Roozbeh
e052784f-2858-4c2d-aff8-2fee6fcd479d
Zhang, Chengchen
abc47c06-4b99-4aed-be72-463f211e9dfa
Cai, Shengxiang
039492d7-7492-4a3e-a909-952eda77d11c
Centurion, Franco
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Xie, Wanjie
718129dc-cebc-4007-a495-a791960284d4
Cao, Zhenbang
2bee3c99-a657-4f91-8a2c-76b301bbab25
Tang, Junma
2c4327a5-96db-427a-ba67-30b9a0907a3d
Rahim, Md Arifur
1a336538-113c-494c-9dd9-04e7f466f323
Zhang, Jin
3368a635-8668-4fbb-8db7-887511fd601a
Razmjou, Amir
8ebb343b-223b-4cad-afd7-a1a917da0faa
Leslie, Greg
1a8ed076-e132-4c26-ac07-049e9fba84b6
Kalantar-Zadeh, Kourosh
aded6a64-8612-40b7-aae9-233fbae916a6
Tang, Jianbo
87473905-8e35-48a1-a776-88080bb751b9
Allioux, Francois Marie
06fa4c1f-9d93-4fa4-bff6-2b4b4d497e95
Merhebi, Salma
1d12f9d9-d9b9-4eb6-b328-b9322c4eaada
Mohammad, Munirah
23b47537-1883-4c4c-8f31-e87abe9b444b
Mayyas, Mohannad
9f9295c4-deda-4289-9cc8-bba31bce5c99
Abbasi, Roozbeh
e052784f-2858-4c2d-aff8-2fee6fcd479d
Zhang, Chengchen
abc47c06-4b99-4aed-be72-463f211e9dfa
Cai, Shengxiang
039492d7-7492-4a3e-a909-952eda77d11c
Centurion, Franco
7b4b6572-ddbb-40d1-a79c-4681933fac76
Xie, Wanjie
718129dc-cebc-4007-a495-a791960284d4
Cao, Zhenbang
2bee3c99-a657-4f91-8a2c-76b301bbab25
Tang, Junma
2c4327a5-96db-427a-ba67-30b9a0907a3d
Rahim, Md Arifur
1a336538-113c-494c-9dd9-04e7f466f323
Zhang, Jin
3368a635-8668-4fbb-8db7-887511fd601a
Razmjou, Amir
8ebb343b-223b-4cad-afd7-a1a917da0faa
Leslie, Greg
1a8ed076-e132-4c26-ac07-049e9fba84b6
Kalantar-Zadeh, Kourosh
aded6a64-8612-40b7-aae9-233fbae916a6
Tang, Jianbo
87473905-8e35-48a1-a776-88080bb751b9
Allioux, Francois Marie
06fa4c1f-9d93-4fa4-bff6-2b4b4d497e95

Merhebi, Salma, Mohammad, Munirah, Mayyas, Mohannad, Abbasi, Roozbeh, Zhang, Chengchen, Cai, Shengxiang, Centurion, Franco, Xie, Wanjie, Cao, Zhenbang, Tang, Junma, Rahim, Md Arifur, Zhang, Jin, Razmjou, Amir, Leslie, Greg, Kalantar-Zadeh, Kourosh, Tang, Jianbo and Allioux, Francois Marie (2021) Post-transition metal/polymer composites for the separation and sensing of alkali metal ions. Journal of Materials Chemistry A, 9 (35), 19854-19864. (doi:10.1039/d1ta02664j).

Record type: Article

Abstract

The separation and sensing of alkali metal ions from aqueous lithium resources is of great importance for building future renewable and lithium-based energy storage technologies. As such, interest arises for the development of functional composites selective to ionic lithium (Li+) over sodium (Na+) and potassium (K+) that allows for a range of low carbon-footprint sensing and recovery processes. Here, selective separation of Li+from aqueous mixtures of Na+and K+ions using polyvinyl alcohol/maleic acid composites was enhanced by the inclusion as nano-additives of post-transition metals gallium (Ga) and indium (In), together with their alloys and oxidized species, in the composite casting process. The co-addition of Ga and In resulted in the spontaneous formation of Ga oxides and hydroxides while In remained in the metallic state. This Ga-In composite was stable in aqueous solutions containing a high concentration (0.1 M) of mixed alkali metal ions over 5 days and achieved exceptionally high selectivities of Li+over Na+(3.8 ± 0.1) and K+(7.1 ± 0.1). Results from an electrochemical sensing platform technique revealed that Li+selectivity was in the same order as the diffusion rates. This work demonstrated that the low-melting-point post-transition metal alloy enables a one-step low energy fabrication of selective polymeric composites with diverse applications for energy, sensing and separation industries. The work has implications for the efficient manufacture of renewable and lithium-based energy storage technologies.

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More information

Accepted/In Press date: 26 May 2021
e-pub ahead of print date: 27 May 2021
Published date: 21 September 2021
Additional Information: Funding Information: This work was supported by the Australian Research Council (ARC) Laureate Fellowship grant (FL180100053). Publisher Copyright: © The Royal Society of Chemistry 2021.

Identifiers

Local EPrints ID: 482312
URI: http://eprints.soton.ac.uk/id/eprint/482312
DOI: doi:10.1039/d1ta02664j
ISSN: 2050-7488
PURE UUID: b21bfe2e-8073-43c0-8de7-8276b8cd16c6
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: Salma Merhebi
Author: Munirah Mohammad
Author: Mohannad Mayyas
Author: Roozbeh Abbasi
Author: Chengchen Zhang ORCID iD
Author: Shengxiang Cai
Author: Franco Centurion
Author: Wanjie Xie
Author: Zhenbang Cao
Author: Junma Tang
Author: Md Arifur Rahim
Author: Jin Zhang
Author: Amir Razmjou
Author: Greg Leslie
Author: Kourosh Kalantar-Zadeh
Author: Jianbo Tang
Author: Francois Marie Allioux

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