MXene as a Charge Storage Host
Тип публикации: Journal Article
Дата публикации: 2018-02-22
SCImago Q1
Tоп 10% SCImago
WOS Q1
БС1
SJR: 5.472
CiteScore: 31.2
Impact factor: 18
ISSN: 00014842, 15204898
PubMed ID:
29469564
General Chemistry
General Medicine
Краткое описание
The development of efficient electrochemical energy storage (EES) devices is an important sustainability issue to realize green electrical grids. Charge storage mechanisms in present EES devices, such as ion (de)intercalation in lithium-ion batteries and electric double layer formation in capacitors, provide insufficient efficiency and performance for grid use. Intercalation pseudocapacitance (or redox capacitance) has emerged as an alternative chemistry for advanced EES devices. Intercalation pseudocapacitance occurs through bulk redox reactions with ultrafast ion diffusion. In particular, the metal carbide/nitride nanosheets termed MXene discovered in 2011 are a promising class of intercalation pseudocapacitor electrode materials because of their compositional versatility for materials exploration (e.g., Ti2CT x, Ti3C2T x, V2CT x, and Nb2CT x, where T is a surface termination group such as F, Cl, O, or OH), high electrical conductivity for high current charge, and a layered structure of stacked nanosheets for ultrafast ion intercalation. Various MXene electrodes have been reported to exhibit complementary battery performance, such as large specific capacity at high charge/discharge rates. However, general design strategies of MXenes for EES applications have not been established because of the limited understanding of the electrochemical mechanisms of MXenes. This Account describes current knowledge of the fundamental electrochemical properties of MXenes and attempts to clarify where intercalation capacitance ends and intercalation pseudocapacitance begins. MXene electrodes in aqueous electrolytes exhibit intercalation of hydrated cations. The hydrated cations form an electric double layer in the interlayer space to give a conventional capacitance within the narrow potential window of aqueous electrolytes. When nonaqueous electrolytes are used, although solvated cations are intercalated into the interlayer space during the initial stage of charging, the confined solvation shell should gradually collapse because of the large inner potential difference in the interlayer space. Upon further charging, desolvated ions solely intercalate, and the atomic orbitals of the desolvated cations overlap with the orbitals of MXene to form a donor band. The formation of the donor band induces the reduction of MXene, giving rise to an intercalation pseudocapacitance through charge transfer from the ions to MXene sheets. Differences in the electrochemical reaction mechanisms lead to variation of the electrochemical responses of MXenes (e.g., cyclic voltammetry curves, specific capacitance), highlighting the importance of establishing a comprehensive grasp of the electrochemical reactions of MXenes at an atomic level. Because of their better charge storage kinetics compared with those of typical materials used in present EES devices, aqueous/nonaqueous asymmetric capacitors using titanium carbide MXene electrodes are capable of efficient operation at high charge/discharge rates. Therefore, the further development of novel MXene electrodes for advanced EES applications is warranted.
Найдено
Ничего не найдено, попробуйте изменить настройки фильтра.
Для доступа к списку цитирований публикации необходимо авторизоваться.
Для доступа к списку профилей, цитирующих публикацию, необходимо авторизоваться.
Топ-30
Журналы
|
2
4
6
8
10
12
14
16
18
|
|
|
Journal of Materials Chemistry A
17 публикаций, 3.88%
|
|
|
Journal of Energy Storage
16 публикаций, 3.65%
|
|
|
Chemical Engineering Journal
15 публикаций, 3.42%
|
|
|
Small
13 публикаций, 2.97%
|
|
|
Energy Storage Materials
11 публикаций, 2.51%
|
|
|
Advanced Functional Materials
11 публикаций, 2.51%
|
|
|
Nanoscale
11 публикаций, 2.51%
|
|
|
Advanced Materials
10 публикаций, 2.28%
|
|
|
Journal of Power Sources
8 публикаций, 1.83%
|
|
|
ACS Nano
8 публикаций, 1.83%
|
|
|
ACS applied materials & interfaces
7 публикаций, 1.6%
|
|
|
Coordination Chemistry Reviews
6 публикаций, 1.37%
|
|
|
ACS Applied Nano Materials
6 публикаций, 1.37%
|
|
|
Small Methods
5 публикаций, 1.14%
|
|
|
Nanomaterials
5 публикаций, 1.14%
|
|
|
Nano-Micro Letters
5 публикаций, 1.14%
|
|
|
Applied Surface Science
5 публикаций, 1.14%
|
|
|
Journal of Colloid and Interface Science
5 публикаций, 1.14%
|
|
|
Journal of Energy Chemistry
5 публикаций, 1.14%
|
|
|
Sustainable Energy and Fuels
5 публикаций, 1.14%
|
|
|
Materials Today
4 публикации, 0.91%
|
|
|
Journal of Physics Energy
4 публикации, 0.91%
|
|
|
Ceramics International
4 публикации, 0.91%
|
|
|
ChemSusChem
4 публикации, 0.91%
|
|
|
Advanced Materials Interfaces
4 публикации, 0.91%
|
|
|
Advanced Energy and Sustainability Research
4 публикации, 0.91%
|
|
|
Energy & Fuels
4 публикации, 0.91%
|
|
|
Chemical Communications
4 публикации, 0.91%
|
|
|
Chemical Reviews
3 публикации, 0.68%
|
|
|
2
4
6
8
10
12
14
16
18
|
Издатели
|
20
40
60
80
100
120
140
160
|
|
|
Elsevier
152 публикации, 34.7%
|
|
|
Wiley
93 публикации, 21.23%
|
|
|
Royal Society of Chemistry (RSC)
58 публикаций, 13.24%
|
|
|
American Chemical Society (ACS)
53 публикации, 12.1%
|
|
|
Springer Nature
31 публикация, 7.08%
|
|
|
MDPI
13 публикаций, 2.97%
|
|
|
IOP Publishing
8 публикаций, 1.83%
|
|
|
AIP Publishing
4 публикации, 0.91%
|
|
|
The Electrochemical Society
4 публикации, 0.91%
|
|
|
Tsinghua University Press
3 публикации, 0.68%
|
|
|
World Scientific
2 публикации, 0.46%
|
|
|
American Association for the Advancement of Science (AAAS)
2 публикации, 0.46%
|
|
|
Chinese Ceramic Society
2 публикации, 0.46%
|
|
|
The Electrochemical Society of Japan
2 публикации, 0.46%
|
|
|
EDP Sciences
2 публикации, 0.46%
|
|
|
Frontiers Media S.A.
1 публикация, 0.23%
|
|
|
Cambridge University Press
1 публикация, 0.23%
|
|
|
Korean Society of Industrial Engineering Chemistry
1 публикация, 0.23%
|
|
|
Taylor & Francis
1 публикация, 0.23%
|
|
|
Institute of Electrical and Electronics Engineers (IEEE)
1 публикация, 0.23%
|
|
|
Optica Publishing Group
1 публикация, 0.23%
|
|
|
20
40
60
80
100
120
140
160
|
- Мы не учитываем публикации, у которых нет DOI.
- Статистика публикаций обновляется еженедельно.
Вы ученый?
Создайте профиль, чтобы получать персональные рекомендации коллег, конференций и новых статей.
Войти с ORCID
Метрики
440
Всего цитирований:
440
Цитирований c 2025:
100
(22.84%)
Цитировать
ГОСТ |
RIS |
BibTex |
MLA
Цитировать
ГОСТ
Скопировать
Okubo M. et al. MXene as a Charge Storage Host // Accounts of Chemical Research. 2018. Vol. 51. No. 3. pp. 591-599.
ГОСТ со всеми авторами (до 50)
Скопировать
Okubo M., Sugahara A., Kajiyama S., Yamada A. MXene as a Charge Storage Host // Accounts of Chemical Research. 2018. Vol. 51. No. 3. pp. 591-599.
Цитировать
RIS
Скопировать
TY - JOUR
DO - 10.1021/acs.accounts.7b00481
UR - https://doi.org/10.1021/acs.accounts.7b00481
TI - MXene as a Charge Storage Host
T2 - Accounts of Chemical Research
AU - Okubo, Masashi
AU - Sugahara, Akira
AU - Kajiyama, Satoshi
AU - Yamada, Atsuo
PY - 2018
DA - 2018/02/22
PB - American Chemical Society (ACS)
SP - 591-599
IS - 3
VL - 51
PMID - 29469564
SN - 0001-4842
SN - 1520-4898
ER -
Цитировать
BibTex (до 50 авторов)
Скопировать
@article{2018_Okubo,
author = {Masashi Okubo and Akira Sugahara and Satoshi Kajiyama and Atsuo Yamada},
title = {MXene as a Charge Storage Host},
journal = {Accounts of Chemical Research},
year = {2018},
volume = {51},
publisher = {American Chemical Society (ACS)},
month = {feb},
url = {https://doi.org/10.1021/acs.accounts.7b00481},
number = {3},
pages = {591--599},
doi = {10.1021/acs.accounts.7b00481}
}
Цитировать
MLA
Скопировать
Okubo, Masashi, et al. “MXene as a Charge Storage Host.” Accounts of Chemical Research, vol. 51, no. 3, Feb. 2018, pp. 591-599. https://doi.org/10.1021/acs.accounts.7b00481.
Ошибка в публикации?