A high-throughput approach developing lithium-niobium-tantalum oxides as electrolyte/cathode interlayers for high-voltage all-solid-state lithium batteries
A high-throughput approach developing lithium-niobium-tantalum oxides as electrolyte/cathode interlayers for high-voltage all-solid-state lithium batteries
The ever-increasing interest in sustainable mobility is driving the development of innovative batteries with increased energy densities relative to currently commercialized lithium-ion batteries. All-solid-state batteries using 5 V-class positive electrodes are one of those batteries due to their larger volumetric energy density and their superior durability. However, their power density tends to be limited by the large charge transfer resistance at their electrolyte/5 V-electrode interfaces; one explanation for this is the development of significant Li+ deficient layers at the interface. Here we propose a new interlayer material that would effectively resolve the Li+ deficient layers. The partially-crystallized Li56Nb22Ta22 oxide was identified using the molecular beam epitaxy (MBE) based high-throughput physical vapor deposition (HT-PVD) approach. Its higher ionic conductivity of 4.2 ?S cm?1 and higher permittivity of 165 when measured at 254 kHz, relative to those of conventional LiNbO3 interlayer (1.8 ?S cm?1 and 95, respectively) will be effective for fast charge transfer reactions at the electrolyte /cathode interfaces in 5 V-class all-solid-state batteries.
A722-A726
Yada, C.
49fa8cd2-a86c-474a-9107-4a3e9c1dd73c
Lee, C.E.
f37cd28b-9244-4ed5-8fee-53848c8edda8
Laughman, D.
9d42b85c-ca44-4b5c-aaf4-f5ac29ab808b
Hannah, L.
6c0ab1ad-f7eb-4496-b6f3-90eec0f87c87
Iba, H.
759dda43-f557-4899-84a8-677807ea7ad6
Hayden, B.E.
aea74f68-2264-4487-9d84-5b12ddbbb331
5 February 2015
Yada, C.
49fa8cd2-a86c-474a-9107-4a3e9c1dd73c
Lee, C.E.
f37cd28b-9244-4ed5-8fee-53848c8edda8
Laughman, D.
9d42b85c-ca44-4b5c-aaf4-f5ac29ab808b
Hannah, L.
6c0ab1ad-f7eb-4496-b6f3-90eec0f87c87
Iba, H.
759dda43-f557-4899-84a8-677807ea7ad6
Hayden, B.E.
aea74f68-2264-4487-9d84-5b12ddbbb331
Yada, C., Lee, C.E., Laughman, D., Hannah, L., Iba, H. and Hayden, B.E.
(2015)
A high-throughput approach developing lithium-niobium-tantalum oxides as electrolyte/cathode interlayers for high-voltage all-solid-state lithium batteries.
Journal of the Electrochemical Society, 162 (4), .
(doi:10.1149/2.0661504jes).
Abstract
The ever-increasing interest in sustainable mobility is driving the development of innovative batteries with increased energy densities relative to currently commercialized lithium-ion batteries. All-solid-state batteries using 5 V-class positive electrodes are one of those batteries due to their larger volumetric energy density and their superior durability. However, their power density tends to be limited by the large charge transfer resistance at their electrolyte/5 V-electrode interfaces; one explanation for this is the development of significant Li+ deficient layers at the interface. Here we propose a new interlayer material that would effectively resolve the Li+ deficient layers. The partially-crystallized Li56Nb22Ta22 oxide was identified using the molecular beam epitaxy (MBE) based high-throughput physical vapor deposition (HT-PVD) approach. Its higher ionic conductivity of 4.2 ?S cm?1 and higher permittivity of 165 when measured at 254 kHz, relative to those of conventional LiNbO3 interlayer (1.8 ?S cm?1 and 95, respectively) will be effective for fast charge transfer reactions at the electrolyte /cathode interfaces in 5 V-class all-solid-state batteries.
Text
J. Electrochem. Soc.-2015-Yada-A722-6.pdf
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Published date: 5 February 2015
Organisations:
Electrochemistry
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Local EPrints ID: 395506
URI: http://eprints.soton.ac.uk/id/eprint/395506
ISSN: 0013-4651
PURE UUID: cd2a7c4c-2e11-4e03-b374-a0d644f24889
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Date deposited: 31 May 2016 11:31
Last modified: 15 Mar 2024 02:36
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Author:
C. Yada
Author:
C.E. Lee
Author:
D. Laughman
Author:
L. Hannah
Author:
H. Iba
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