Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling
Wentao Liang
1
,
Hong Liang
2
,
H. Yang
1
,
Feifei Fan
3
,
Yang Liu
4
,
Hong Li
5
,
Ju Li
6
,
Jianyu Huang
4
,
Long Chen
2
,
Ting Zhu
3
,
Sulin Zhang
1
4
Publication type: Journal Article
Publication date: 2013-10-11
scimago Q1
wos Q1
SJR: 2.967
CiteScore: 14.9
Impact factor: 9.1
ISSN: 15306984, 15306992
PubMed ID:
24102207
General Chemistry
Condensed Matter Physics
General Materials Science
Mechanical Engineering
Bioengineering
Abstract
The irreversible chemomechanical degradation is a critical issue in the development of high-capacity electrode materials for the next-generation lithium (Li)-ion batteries. Here we report the self-healing behavior of gallium nanodroplets (GaNDs) under electrochemical cycling at room temperature, observed with in situ transmission electron microscopy (TEM). During lithiation, the GaNDs underwent a liquid-to-solid phase transition, forming a crystalline phase (LixGa) with ~160% volume expansion. Owing to the uneven Li flow during lithiation, the fully lithiated GaNDs exhibited highly distorted morphologies. Upon delithiation, the reverse phase transition occurred, accompanied with the nucleation and growth of a nanosized void. After the GaNDs were fully delithiated, the nanovoid gradually annihilated. Our analysis, along with phase field modeling and experimental measurements of the void growth and annihilation, provides mechanistic insights into the void formation and annihilation mechanism. The GaNDs may function as an effective healing agent in durable composite electrodes for high-performance Li-ion batteries, wherein active components, such as Si, are susceptible to fracture.
Found
Nothing found, try to update filter.
Found
Nothing found, try to update filter.
Top-30
Journals
|
2
4
6
8
10
|
|
|
ACS applied materials & interfaces
10 publications, 8.93%
|
|
|
Advanced Materials
5 publications, 4.46%
|
|
|
Nanoscale
5 publications, 4.46%
|
|
|
Journal of Materials Chemistry A
5 publications, 4.46%
|
|
|
Small
4 publications, 3.57%
|
|
|
Nano Letters
4 publications, 3.57%
|
|
|
ACS Applied Energy Materials
4 publications, 3.57%
|
|
|
Journal of Energy Storage
3 publications, 2.68%
|
|
|
Nano Energy
3 publications, 2.68%
|
|
|
Electrochimica Acta
3 publications, 2.68%
|
|
|
Advanced Functional Materials
2 publications, 1.79%
|
|
|
Journal of the Electrochemical Society
2 publications, 1.79%
|
|
|
Nanomaterials
2 publications, 1.79%
|
|
|
Journal of Energy Chemistry
2 publications, 1.79%
|
|
|
Energy Storage Materials
2 publications, 1.79%
|
|
|
Materials Letters
2 publications, 1.79%
|
|
|
Advanced Energy Materials
2 publications, 1.79%
|
|
|
Journal of the American Chemical Society
2 publications, 1.79%
|
|
|
Journal of Physical Chemistry C
2 publications, 1.79%
|
|
|
ACS Nano
2 publications, 1.79%
|
|
|
Energy and Environmental Science
2 publications, 1.79%
|
|
|
Dalton Transactions
2 publications, 1.79%
|
|
|
npj Computational Materials
1 publication, 0.89%
|
|
|
Nature Communications
1 publication, 0.89%
|
|
|
Electrochemical Energy Reviews
1 publication, 0.89%
|
|
|
Nature Nanotechnology
1 publication, 0.89%
|
|
|
Scientific Reports
1 publication, 0.89%
|
|
|
Scripta Materialia
1 publication, 0.89%
|
|
|
Composites Part B: Engineering
1 publication, 0.89%
|
|
|
2
4
6
8
10
|
Publishers
|
5
10
15
20
25
30
35
|
|
|
Elsevier
32 publications, 28.57%
|
|
|
American Chemical Society (ACS)
28 publications, 25%
|
|
|
Wiley
20 publications, 17.86%
|
|
|
Royal Society of Chemistry (RSC)
19 publications, 16.96%
|
|
|
Springer Nature
5 publications, 4.46%
|
|
|
The Electrochemical Society
2 publications, 1.79%
|
|
|
MDPI
2 publications, 1.79%
|
|
|
IOP Publishing
1 publication, 0.89%
|
|
|
AIP Publishing
1 publication, 0.89%
|
|
|
OOO Zhurnal "Mendeleevskie Soobshcheniya"
1 publication, 0.89%
|
|
|
The Royal Society
1 publication, 0.89%
|
|
|
5
10
15
20
25
30
35
|
- We do not take into account publications without a DOI.
- Statistics recalculated weekly.
Are you a researcher?
Create a profile to get free access to personal recommendations for colleagues and new articles.
Metrics
112
Total citations:
112
Citations from 2025:
15
(13.39%)
Cite this
GOST |
RIS |
BibTex |
MLA
Cite this
GOST
Copy
Liang W. et al. Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling // Nano Letters. 2013. Vol. 13. No. 11. pp. 5212-5217.
GOST all authors (up to 50)
Copy
Liang W., Liang H., Yang H., Fan F., Liu Y., Li H., Li J., Huang J., Chen L., Zhu T., Zhang S. Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling // Nano Letters. 2013. Vol. 13. No. 11. pp. 5212-5217.
Cite this
RIS
Copy
TY - JOUR
DO - 10.1021/nl402644w
UR - https://doi.org/10.1021/nl402644w
TI - Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling
T2 - Nano Letters
AU - Liang, Wentao
AU - Liang, Hong
AU - Yang, H.
AU - Fan, Feifei
AU - Liu, Yang
AU - Li, Hong
AU - Li, Ju
AU - Huang, Jianyu
AU - Chen, Long
AU - Zhu, Ting
AU - Zhang, Sulin
PY - 2013
DA - 2013/10/11
PB - American Chemical Society (ACS)
SP - 5212-5217
IS - 11
VL - 13
PMID - 24102207
SN - 1530-6984
SN - 1530-6992
ER -
Cite this
BibTex (up to 50 authors)
Copy
@article{2013_Liang,
author = {Wentao Liang and Hong Liang and H. Yang and Feifei Fan and Yang Liu and Hong Li and Ju Li and Jianyu Huang and Long Chen and Ting Zhu and Sulin Zhang},
title = {Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling},
journal = {Nano Letters},
year = {2013},
volume = {13},
publisher = {American Chemical Society (ACS)},
month = {oct},
url = {https://doi.org/10.1021/nl402644w},
number = {11},
pages = {5212--5217},
doi = {10.1021/nl402644w}
}
Cite this
MLA
Copy
Liang, Wentao, et al. “Nanovoid Formation and Annihilation in Gallium Nanodroplets under Lithiation–Delithiation Cycling.” Nano Letters, vol. 13, no. 11, Oct. 2013, pp. 5212-5217. https://doi.org/10.1021/nl402644w.