Enhanced ion intercalation in NixK1−2xTiNbO5 enabled by redox active Ni exchange for potassium-ion batteries
Enhanced ion intercalation in NixK1−2xTiNbO5 enabled by redox active Ni exchange for potassium-ion batteries
The ultimate goal of potassium-ion batteries (KIBs) is to become a serious competitor to lithium-ion batteries (LIBs). Achieving this requires the development of high energy density negative electrode materials, with transition metal oxides emerging as the most promising candidates. However, despite their high theoretical capacities, most transition metal oxides still struggle to achieve high performance, often necessitating substantial nanostructuring. Ion-exchange presents a facile and effective process for enhancing material properties, yet the demonstration of the exchanged ions undergoing redox activity has not been previously reported for KIBs. Herein, this work reports Ni0.25K0.5TiNbO5, synthesized through the ion-exchange between K+ and Ni2+, as a novel negative electrode material for KIBs. The ion-exchanged material achieves a specific capacity of 304 mAh g−1 in the first cycle and 162 mAh g−1 after 10 cycles, corresponding to a 240% and 156% increase compared to the pristine, unexchanged KTiNbO5 at the same cycle numbers. The structure-performance relationship was investigated in detail, shedding light on the previously unknown relationships between the level of hydration, degree of exchange and the performance of ion-exchanged materials. Furthermore, the exchanged Ni was demonstrated to be reversibly redox active, contributing to the observed capacity and representing a first for ion-exchanged materials in the KIB literature.
19140-19153
Nason, Charlie A.F.
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Vijaya Kumar Saroja, Ajay Piriya
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Ren, Wanjun
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Mei, Yingkangzi
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Sarguroh, Asma
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Han, Yupei
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Lu, Yi
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Gould, Jamie A.
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Hyde, Tim I.
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Celorrio, Veronica
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Sankar, Gopinathan
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Xu, Yang
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Nason, Charlie A.F.
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Vijaya Kumar Saroja, Ajay Piriya
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Ren, Wanjun
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Mei, Yingkangzi
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Sarguroh, Asma
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Han, Yupei
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Lu, Yi
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Gould, Jamie A.
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Hyde, Tim I.
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Celorrio, Veronica
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Sankar, Gopinathan
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Xu, Yang
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Nason, Charlie A.F., Vijaya Kumar Saroja, Ajay Piriya, Ren, Wanjun, Mei, Yingkangzi, Sarguroh, Asma, Han, Yupei, Lu, Yi, Gould, Jamie A., Hyde, Tim I., Celorrio, Veronica, Sankar, Gopinathan and Xu, Yang
(2025)
Enhanced ion intercalation in NixK1−2xTiNbO5 enabled by redox active Ni exchange for potassium-ion batteries.
Chemical Science, 41, .
(doi:10.1039/d5sc04984a).
Abstract
The ultimate goal of potassium-ion batteries (KIBs) is to become a serious competitor to lithium-ion batteries (LIBs). Achieving this requires the development of high energy density negative electrode materials, with transition metal oxides emerging as the most promising candidates. However, despite their high theoretical capacities, most transition metal oxides still struggle to achieve high performance, often necessitating substantial nanostructuring. Ion-exchange presents a facile and effective process for enhancing material properties, yet the demonstration of the exchanged ions undergoing redox activity has not been previously reported for KIBs. Herein, this work reports Ni0.25K0.5TiNbO5, synthesized through the ion-exchange between K+ and Ni2+, as a novel negative electrode material for KIBs. The ion-exchanged material achieves a specific capacity of 304 mAh g−1 in the first cycle and 162 mAh g−1 after 10 cycles, corresponding to a 240% and 156% increase compared to the pristine, unexchanged KTiNbO5 at the same cycle numbers. The structure-performance relationship was investigated in detail, shedding light on the previously unknown relationships between the level of hydration, degree of exchange and the performance of ion-exchanged materials. Furthermore, the exchanged Ni was demonstrated to be reversibly redox active, contributing to the observed capacity and representing a first for ion-exchanged materials in the KIB literature.
Text
d5sc04984a
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Accepted/In Press date: 12 September 2025
e-pub ahead of print date: 15 October 2025
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This journal is © The Royal Society of Chemistry.
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Local EPrints ID: 506838
URI: http://eprints.soton.ac.uk/id/eprint/506838
ISSN: 2041-6520
PURE UUID: c5467249-aeb2-4b19-ba3f-1fe4d84505ee
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Date deposited: 18 Nov 2025 18:18
Last modified: 20 Nov 2025 03:08
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Contributors
Author:
Charlie A.F. Nason
Author:
Ajay Piriya Vijaya Kumar Saroja
Author:
Wanjun Ren
Author:
Yingkangzi Mei
Author:
Asma Sarguroh
Author:
Yupei Han
Author:
Yi Lu
Author:
Jamie A. Gould
Author:
Tim I. Hyde
Author:
Veronica Celorrio
Author:
Gopinathan Sankar
Author:
Yang Xu
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