Journal of Materials Chemistry A, volume 10, issue 43, pages 23185-23194
Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries
Publication type: Journal Article
Publication date: 2022-10-24
Journal:
Journal of Materials Chemistry A
Quartile SCImago
Q1
Quartile WOS
Q1
Impact factor: 11.9
ISSN: 20507488, 20507496, 09599428, 13645501
General Chemistry
General Materials Science
Renewable Energy, Sustainability and the Environment
Abstract
A LISICON-type oxide solid electrolyte has superior chemical/electrochemical compatibilities with high capacity Ni-rich layered oxides and Li metal. LISICON based solid-state battery via co-sintering process operates well at room temperature.
Top-30
Citations by journals
|
1
|
|
|
Nano-Micro Letters
1 publication, 12.5%
|
|
|
ChemSusChem
1 publication, 12.5%
|
|
|
Advanced Engineering Materials
1 publication, 12.5%
|
|
|
Journal of Materials Science: Materials in Electronics
1 publication, 12.5%
|
|
|
ACS Applied Energy Materials
1 publication, 12.5%
|
|
|
ChemElectroChem
1 publication, 12.5%
|
|
|
Russian Chemical Reviews
1 publication, 12.5%
|
|
|
Journal of Energy Storage
1 publication, 12.5%
|
|
|
1
|
Citations by publishers
|
1
2
3
|
|
|
Wiley
3 publications, 37.5%
|
|
|
Springer Nature
2 publications, 25%
|
|
|
American Chemical Society (ACS)
1 publication, 12.5%
|
|
|
Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii
1 publication, 12.5%
|
|
|
Elsevier
1 publication, 12.5%
|
|
|
1
2
3
|
- We do not take into account publications without a DOI.
- Statistics recalculated only for publications connected to researchers, organizations and labs registered on the platform.
- Statistics recalculated weekly.
{"yearsCitations":{"type":"bar","data":{"show":true,"labels":[2023,2024],"ids":[0,0],"codes":[0,0],"imageUrls":["",""],"datasets":[{"label":"Citations number","data":[5,3],"backgroundColor":["#3B82F6","#3B82F6"],"percentage":["62.5","37.5"],"barThickness":null}]},"options":{"indexAxis":"x","maintainAspectRatio":true,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false},"x":{"ticks":{"stepSize":1,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Citations per year","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"journals":{"type":"bar","data":{"show":true,"labels":["Nano-Micro Letters","ChemSusChem","Advanced Engineering Materials","Journal of Materials Science: Materials in Electronics","ACS Applied Energy Materials","ChemElectroChem","Russian Chemical Reviews","Journal of Energy Storage"],"ids":[7765,6896,18649,20208,6419,22483,23802,18623],"codes":[0,0,0,0,0,0,0,0],"imageUrls":["\/storage\/images\/resized\/voXLqlsvTwv5p3iMQ8Dhs95nqB4AXOG7Taj7G4ra_medium.webp","\/storage\/images\/resized\/bRyGpdm98BkAUYiK1YFNpl5Z7hPu6Gd87gbIeuG3_medium.webp","\/storage\/images\/resized\/bRyGpdm98BkAUYiK1YFNpl5Z7hPu6Gd87gbIeuG3_medium.webp","\/storage\/images\/resized\/voXLqlsvTwv5p3iMQ8Dhs95nqB4AXOG7Taj7G4ra_medium.webp","\/storage\/images\/resized\/iLiQsFqFaSEx6chlGQ5fbAwF6VYU3WWa08hkss0g_medium.webp","\/storage\/images\/resized\/bRyGpdm98BkAUYiK1YFNpl5Z7hPu6Gd87gbIeuG3_medium.webp","\/storage\/images\/resized\/9Mus3KG1Tkd7Bwaurt8H3RwWh0CxRlGoO6ng9UK1_medium.webp","\/storage\/images\/resized\/GDnYOu1UpMMfMMRV6Aqle4H0YLLsraeD9IP9qScG_medium.webp"],"datasets":[{"label":"","data":[1,1,1,1,1,1,1,1],"backgroundColor":["#3B82F6","#3B82F6","#3B82F6","#3B82F6","#3B82F6","#3B82F6","#3B82F6","#3B82F6"],"percentage":[12.5,12.5,12.5,12.5,12.5,12.5,12.5,12.5],"barThickness":13}]},"options":{"indexAxis":"y","maintainAspectRatio":false,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false},"x":{"ticks":{"stepSize":null,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Journals","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"publishers":{"type":"bar","data":{"show":true,"labels":["Wiley","Springer Nature","American Chemical Society (ACS)","Autonomous Non-profit Organization Editorial Board of the journal Uspekhi Khimii","Elsevier"],"ids":[11,8,40,9422,17],"codes":[0,0,0,0,0],"imageUrls":["\/storage\/images\/resized\/bRyGpdm98BkAUYiK1YFNpl5Z7hPu6Gd87gbIeuG3_medium.webp","\/storage\/images\/resized\/voXLqlsvTwv5p3iMQ8Dhs95nqB4AXOG7Taj7G4ra_medium.webp","\/storage\/images\/resized\/iLiQsFqFaSEx6chlGQ5fbAwF6VYU3WWa08hkss0g_medium.webp","\/storage\/images\/resized\/9Mus3KG1Tkd7Bwaurt8H3RwWh0CxRlGoO6ng9UK1_medium.webp","\/storage\/images\/resized\/GDnYOu1UpMMfMMRV6Aqle4H0YLLsraeD9IP9qScG_medium.webp"],"datasets":[{"label":"","data":[3,2,1,1,1],"backgroundColor":["#3B82F6","#3B82F6","#3B82F6","#3B82F6","#3B82F6"],"percentage":[37.5,25,12.5,12.5,12.5],"barThickness":13}]},"options":{"indexAxis":"y","maintainAspectRatio":false,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false},"x":{"ticks":{"stepSize":null,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":false}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Publishers","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"yearsCitationsQuartiles":{"type":"bar","data":{"show":true,"labels":[2023,2024],"ids":[],"codes":[],"imageUrls":[],"datasets":[{"label":"Q4","backgroundColor":"rgb(221,90,78)","data":[0,0],"percentage":["0","0"]},{"label":"Q3","backgroundColor":"rgb(251, 163,83)","data":[0,0],"percentage":["0","0"]},{"label":"Q2","backgroundColor":"rgb(232, 213, 89)","data":[1,0],"percentage":["12.5","0"]},{"label":"Q1","backgroundColor":"rgb(164, 207, 99)","data":[4,3],"percentage":["50","37.5"]},{"label":"Quartile not defined","backgroundColor":"#E5E7EB","data":[0,0],"percentage":["0","0"]}]},"options":{"indexAxis":"x","maintainAspectRatio":true,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":true},"x":{"ticks":{"stepSize":1,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":true}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Citations quartiles by SCImago per year","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}},"yearsCitationsQuartilesWs":{"type":"bar","data":{"show":true,"labels":[2023,2024],"ids":[],"codes":[],"imageUrls":[],"datasets":[{"label":"Q4","backgroundColor":"rgb(221,90,78)","data":[0,0],"percentage":["0","0"]},{"label":"Q3","backgroundColor":"rgb(251, 163,83)","data":[0,0],"percentage":["0","0"]},{"label":"Q2","backgroundColor":"rgb(232, 213, 89)","data":[2,1],"percentage":["25","12.5"]},{"label":"Q1","backgroundColor":"rgb(164, 207, 99)","data":[3,2],"percentage":["37.5","25"]},{"label":"Quartile not defined","backgroundColor":"#E5E7EB","data":[0,0],"percentage":["0","0"]}]},"options":{"indexAxis":"x","maintainAspectRatio":true,"scales":{"y":{"ticks":{"precision":0,"autoSkip":false,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":true},"x":{"ticks":{"stepSize":1,"precision":0,"font":{"family":"Montserrat"},"color":"#000000"},"stacked":true}},"plugins":{"legend":{"position":"top","labels":{"font":{"family":"Montserrat"},"color":"#000000"}},"title":{"display":true,"text":"Citations quartiles by WoS per year","font":{"size":24,"family":"Montserrat","weight":600},"color":"#000000"}}}}}
Are you a researcher?
Create a profile to get free access to personal recommendations for colleagues and new articles.
Metrics
Cite this
GOST |
RIS |
BibTex |
MLA
Cite this
GOST
Copy
Woo S., Kang B. Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries // Journal of Materials Chemistry A. 2022. Vol. 10. No. 43. pp. 23185-23194.
GOST all authors (up to 50)
Copy
Woo S., Kang B. Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries // Journal of Materials Chemistry A. 2022. Vol. 10. No. 43. pp. 23185-23194.
Cite this
RIS
Copy
TY - JOUR
DO - 10.1039/d2ta05948g
UR - https://doi.org/10.1039/d2ta05948g
TI - Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries
T2 - Journal of Materials Chemistry A
AU - Woo, Seungjun
AU - Kang, Byoungwoo
PY - 2022
DA - 2022/10/24 00:00:00
PB - Royal Society of Chemistry (RSC)
SP - 23185-23194
IS - 43
VL - 10
SN - 2050-7488
SN - 2050-7496
SN - 0959-9428
SN - 1364-5501
ER -
Cite this
BibTex
Copy
@article{2022_Woo,
author = {Seungjun Woo and Byoungwoo Kang},
title = {Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries},
journal = {Journal of Materials Chemistry A},
year = {2022},
volume = {10},
publisher = {Royal Society of Chemistry (RSC)},
month = {oct},
url = {https://doi.org/10.1039/d2ta05948g},
number = {43},
pages = {23185--23194},
doi = {10.1039/d2ta05948g}
}
Cite this
MLA
Copy
Woo, Seungjun, and Byoungwoo Kang. “Superior compatibilities of a LISICON-type oxide solid electrolyte enable high energy density all-solid-state batteries.” Journal of Materials Chemistry A, vol. 10, no. 43, Oct. 2022, pp. 23185-23194. https://doi.org/10.1039/d2ta05948g.