Self-standing TiC-modified carbon fibre electrodes derived from cellulose and their use as an ultrahigh efficiency lithium metal anode
Self-standing TiC-modified carbon fibre electrodes derived from cellulose and their use as an ultrahigh efficiency lithium metal anode
Lithium metal anodes could be a key component of high energy density rechargeable batteries, but uncontrolled growth of Li dendrites, large volume expansion, and unstable solid electrolyte interface films seriously hinder the practical applications of Li metal batteries. In this work, a self-standing three-dimensional TiC-modified carbon fibre (TiC@C) network has been fabricated by carbothermal reduction. Binding energy calculations reveal that Li is preferentially plated on TiC rather than the bare C skeleton. The lithiophilic TiC not only serves as a Li nucleation site to assist homogeneous Li deposition, but it also enables rapid Li deposition due to its high electronic conductivity. The 3D conductive structures with high surface area play an important role in reducing the local current density, and also accommodate Li volume changes during repeated cycling. As a result, the TiC@C electrode achieves a nearly zero Li nucleation overpotential and low voltage hysteresis of 150 mV at 2 mA cm
−2. Passing 1 mA h cm
−2 charge, the coulombic efficiency (CE) was found to be 99.6% over more than 200 cycles. Furthermore, full cells assembled with a LiFePO
4 cathode in a conventional carbonate electrolyte achieve an impressive capacity retention of 87% over 250 cycles. This work demonstrates a novel design of a 3D lithiophilic host for dendrite-free lithium metal anodes.
15444-15455
Wang, Junren
78a8d0c3-7442-4d45-a1c3-718a357aa2cb
Zhong, Huimian
145c076e-e6f9-4a73-a545-6440b2eb78f5
Liu, Bowen
432d1550-1946-452b-aa84-2a80963cafbf
Zhang, Min
dfc78617-c6bf-40d9-a643-427ba8f2c24f
Hector, Andrew L.
f19a8f31-b37f-4474-b32a-b7cf05b9f0e5
Russell, Andrea E.
b6b7c748-efc1-4d5d-8a7a-8e4b69396169
26 June 2023
Wang, Junren
78a8d0c3-7442-4d45-a1c3-718a357aa2cb
Zhong, Huimian
145c076e-e6f9-4a73-a545-6440b2eb78f5
Liu, Bowen
432d1550-1946-452b-aa84-2a80963cafbf
Zhang, Min
dfc78617-c6bf-40d9-a643-427ba8f2c24f
Hector, Andrew L.
f19a8f31-b37f-4474-b32a-b7cf05b9f0e5
Russell, Andrea E.
b6b7c748-efc1-4d5d-8a7a-8e4b69396169
Wang, Junren, Zhong, Huimian, Liu, Bowen, Zhang, Min, Hector, Andrew L. and Russell, Andrea E.
(2023)
Self-standing TiC-modified carbon fibre electrodes derived from cellulose and their use as an ultrahigh efficiency lithium metal anode.
Journal of Materials Chemistry A, 11 (28), .
(doi:10.1039/D3TA01707A).
Abstract
Lithium metal anodes could be a key component of high energy density rechargeable batteries, but uncontrolled growth of Li dendrites, large volume expansion, and unstable solid electrolyte interface films seriously hinder the practical applications of Li metal batteries. In this work, a self-standing three-dimensional TiC-modified carbon fibre (TiC@C) network has been fabricated by carbothermal reduction. Binding energy calculations reveal that Li is preferentially plated on TiC rather than the bare C skeleton. The lithiophilic TiC not only serves as a Li nucleation site to assist homogeneous Li deposition, but it also enables rapid Li deposition due to its high electronic conductivity. The 3D conductive structures with high surface area play an important role in reducing the local current density, and also accommodate Li volume changes during repeated cycling. As a result, the TiC@C electrode achieves a nearly zero Li nucleation overpotential and low voltage hysteresis of 150 mV at 2 mA cm
−2. Passing 1 mA h cm
−2 charge, the coulombic efficiency (CE) was found to be 99.6% over more than 200 cycles. Furthermore, full cells assembled with a LiFePO
4 cathode in a conventional carbonate electrolyte achieve an impressive capacity retention of 87% over 250 cycles. This work demonstrates a novel design of a 3D lithiophilic host for dendrite-free lithium metal anodes.
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Accepted/In Press date: 26 June 2023
e-pub ahead of print date: 26 June 2023
Published date: 26 June 2023
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Funding Information:
JW thanks the China Scholarship Council for funding. The authors also thank EPSRC for funding equipment used in this work under EP/K00509x/1, EP/K009877/1 and EP/V007629/1, and Nikolay Zhelev for SEM training and help with imaging the morphology of Li dendrites.
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© 2023 The Royal Society of Chemistry
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Local EPrints ID: 478642
URI: http://eprints.soton.ac.uk/id/eprint/478642
ISSN: 2050-7488
PURE UUID: 7b7c860b-7f77-49d6-9b74-11a5baea5a44
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Date deposited: 06 Jul 2023 16:39
Last modified: 06 Jun 2024 02:05
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Author:
Junren Wang
Author:
Huimian Zhong
Author:
Bowen Liu
Author:
Min Zhang
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