Interface-controlled phase separation of liquid metal-based eutectic ternary alloys
Interface-controlled phase separation of liquid metal-based eutectic ternary alloys
Liquid metals (LMs) are immiscible in many common electrolytic solutions and, when immersed in them, establish phase boundaries that display intriguing interfacial characteristics. The application of a cathodic potential to such interfaces may trigger phase separation of solute elements out of the LMs. Here, we investigate this possibility in two of the most researched and industrially used eutectic ternary LMs of Galinstan (Ga-In-Sn) and Field's metal (FM, In-Bi-Sn). We observe that upon surface perturbation by an applied electric potential, solute elements compete to segregate out of the LM alloys according to their energy levels. The nature of the electrolytic solutions plays a key role in the separation process as they dictate whether solute metals are expelled selectively in their pure form or as binary compounds. For example, in a phosphate-based aqueous electrolyte, nano-sized Sn-based entities are selectively expelled from Galinstan, while only Bi-based structures leave the surface of FM. In contrast, in a non-aqueous electrolyte, nano-sized binary compounds of Sn-In and Bi-Sn are separated from the surfaces of Galinstan and FM, respectively. We show that selectivity in the surface separation process, achieved by the alteration of the electrolytic solutions, is due to the interplay between the electrodynamic interactions and the electrocapillary effect. This study presents two key findings: (a) it is essential to carefully consider the possibility of component separation in electrochemical systems based on LMs and (b) it demonstrates interfacial metallurgical pathways to process alloys for refining metals into specific purities, component ratios, and dimensions.
10761-10771
Baharfar, Mahroo
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Zheng, Jiewei
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Abbasi, Roozbeh
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Lim, Sean
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Kundi, Varun
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Kumar, Priyank V.
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Rahim, Md Arifur
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Zhang, Chengchen
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Kalantar-Zadeh, Kourosh
aded6a64-8612-40b7-aae9-233fbae916a6
Mayyas, Mohannad
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13 December 2022
Baharfar, Mahroo
4f5e3122-2402-4c84-8513-cf24eeacf3ff
Zheng, Jiewei
11de5ac2-710f-48b5-b97f-cc89b222fcfc
Abbasi, Roozbeh
e052784f-2858-4c2d-aff8-2fee6fcd479d
Lim, Sean
e564c3e0-4908-43ad-94dd-5942e4087c58
Kundi, Varun
7a4c21b1-aca3-4f00-9a5d-6d576c306850
Kumar, Priyank V.
219090eb-6629-44a8-9fac-cc66190bba3d
Rahim, Md Arifur
1a336538-113c-494c-9dd9-04e7f466f323
Zhang, Chengchen
abc47c06-4b99-4aed-be72-463f211e9dfa
Kalantar-Zadeh, Kourosh
aded6a64-8612-40b7-aae9-233fbae916a6
Mayyas, Mohannad
9f9295c4-deda-4289-9cc8-bba31bce5c99
Baharfar, Mahroo, Zheng, Jiewei, Abbasi, Roozbeh, Lim, Sean, Kundi, Varun, Kumar, Priyank V., Rahim, Md Arifur, Zhang, Chengchen, Kalantar-Zadeh, Kourosh and Mayyas, Mohannad
(2022)
Interface-controlled phase separation of liquid metal-based eutectic ternary alloys.
Chemistry of Materials, 34 (23), .
(doi:10.1021/acs.chemmater.2c02981).
Abstract
Liquid metals (LMs) are immiscible in many common electrolytic solutions and, when immersed in them, establish phase boundaries that display intriguing interfacial characteristics. The application of a cathodic potential to such interfaces may trigger phase separation of solute elements out of the LMs. Here, we investigate this possibility in two of the most researched and industrially used eutectic ternary LMs of Galinstan (Ga-In-Sn) and Field's metal (FM, In-Bi-Sn). We observe that upon surface perturbation by an applied electric potential, solute elements compete to segregate out of the LM alloys according to their energy levels. The nature of the electrolytic solutions plays a key role in the separation process as they dictate whether solute metals are expelled selectively in their pure form or as binary compounds. For example, in a phosphate-based aqueous electrolyte, nano-sized Sn-based entities are selectively expelled from Galinstan, while only Bi-based structures leave the surface of FM. In contrast, in a non-aqueous electrolyte, nano-sized binary compounds of Sn-In and Bi-Sn are separated from the surfaces of Galinstan and FM, respectively. We show that selectivity in the surface separation process, achieved by the alteration of the electrolytic solutions, is due to the interplay between the electrodynamic interactions and the electrocapillary effect. This study presents two key findings: (a) it is essential to carefully consider the possibility of component separation in electrochemical systems based on LMs and (b) it demonstrates interfacial metallurgical pathways to process alloys for refining metals into specific purities, component ratios, and dimensions.
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More information
e-pub ahead of print date: 20 November 2022
Published date: 13 December 2022
Additional Information:
Funding Information:
This work was supported by the Australian Research Council (ARC) Laureate Fellowship grant (FL180100053). M.B. acknowledges the financial support through the Australian government research training program and university postgraduate award scholarships. The authors would like to acknowledge the technical assistance of the Mark Wainwright Analytical Centre at UNSW.
Publisher Copyright:
© 2022 American Chemical Society.
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Local EPrints ID: 482928
URI: http://eprints.soton.ac.uk/id/eprint/482928
ISSN: 0897-4756
PURE UUID: 0bfa290b-4a8d-4583-8dce-8820e9bfd06c
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Date deposited: 17 Oct 2023 16:47
Last modified: 06 Jun 2024 02:19
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Contributors
Author:
Mahroo Baharfar
Author:
Jiewei Zheng
Author:
Roozbeh Abbasi
Author:
Sean Lim
Author:
Varun Kundi
Author:
Priyank V. Kumar
Author:
Md Arifur Rahim
Author:
Chengchen Zhang
Author:
Kourosh Kalantar-Zadeh
Author:
Mohannad Mayyas
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