Multifunctional quasi-solid state electrolytes based on "reverse" plant cell structure for high-performance lithium metal batteries

被引：1

作者：

Liu, Zixin ^{[1
]}

Wu, Feng ^{[1
,2
,3
]}

Zhang, Xixue ^{[1
]}

Sun, Xuan ^{[1
,2
]}

Yang, Binbin ^{[1
]}

Sun, Wen ^{[1
]}

Chen, Renjie ^{[1
,2
,3
]}

Li, Li ^{[1
,2
,3
]}

机构：

[1] Beijing Inst Technol, Sch Mat Sci & Engn, Beijing Key Lab Environm Sci & Engn, Beijing 100081, Peoples R China

[2] Beijing Inst Technol, Adv Technol Res Inst, Jinan 250300, Peoples R China

[3] Collaborat Innovat Ctr Elect Vehicles Beijing, Beijing 100081, Peoples R China

来源：

ENERGY STORAGE MATERIALS | 2024年 / 72卷

基金：

北京市自然科学基金; 中国国家自然科学基金;

关键词：

Reverse" plant cell structure; Quasi-solid state electrolytes; Lithium metal batteries; Multifunctional bilayer architecture; ION;

D O I：

10.1016/j.ensm.2024.103767

中图分类号：

O64 [物理化学（理论化学）、化学物理学];

学科分类号：

070304 ; 081704 ;

摘要：

Quasi-solid state electrolytes (QSSEs) combine the benefits of both solid and liquid electrolytes, making them promising for high-performance lithium metal batteries (LMBs). However, developing QSSEs that achieve high ionic conductivity, a continuous electrode/electrolyte interface, and significant mechanical robustness remains challenging. Plant cell walls provide mechanical strength, while the cell membrane offers excellent material transport capabilities, making them effective models for quasi-solid electrolytes. However, using plant cells as a model can result in poor interface contacts due to the rigid components on the exterior. To address this, a "reverse" plant cell QSSE with a multifunctional bilayer architecture has been proposed. The outer layer acts as a functional reaction interface to enhance Li+ transmission, improve interfacial contact, and significantly reduce interfacial impedance. Meanwhile, the inner layer is designed to provide mechanical robustness and shorten ion transport distances. The QSSE inspired by "reverse" plant cells has an ionic conductivity of 4.26 x 10(-3) S cm(-1), a Li+ transference number (t(Li+)) of 0.91, and an electrochemical stability window (ESW) of 4.83 V. Li-LiFePO4 (LFP) full cells based on the "reverse" plant cell QSSE can maintain a cycling capacity of 137 mAh g(-1) after 500 cycles at 1 C, with 95 % retention.

引用

页数：8

共 50 条

[11] Confining Ionic Liquids in Developing Quasi-Solid-State Electrolytes for Lithium Metal Batteries
Hu, Haiman
Li, Jiajia
Ji, Xiaoyan
CHEMISTRY-A EUROPEAN JOURNAL, 2024, 30 (05)
[12] Multifunctional aramid-based composite quasi-solid-state electrolytes for flexible structure batteries
He, Wenjie
Li, Zhigang
Gu, Jingzeng
Qin, Gang
Yang, Jia
Cao, Xinxin
Zhang, Min
Jiang, Jiangmin
JOURNAL OF COLLOID AND INTERFACE SCIENCE, 2025, 680 : 77 - 84
[13] Host-Guest Interactions and Transport Mechanism in Poly(vinylidene fluoride)-Based Quasi-Solid Electrolytes for Lithium Metal Batteries
Vallana, Nicholas
Carena, Eleonora
Ceribelli, Nicole
Mezzomo, Lorenzo
Di Liberto, Giovanni
Mauri, Michele
Ferrara, Chiara
Lorenzi, Roberto
Giordano, Livia
Ruffo, Riccardo
Mustarelli, Piercarlo
ACS APPLIED ENERGY MATERIALS, 2024, 7 (04) : 1606 - 1617
[14] Reinforcing concentrated phosphate electrolytes with in-situ polymerized skeletons for robust quasi-solid lithium metal batteries
Chen, Jiahua
Yang, Zheng
Liu, Guohua
Li, Cheng
Yi, Jingsi
Fan, Ming
Tan, Huaping
Lu, Ziheng
Yang, Chunlei
ENERGY STORAGE MATERIALS, 2020, 25 : 305 - 312
[15] Reconstructing the Li* solvation structure in quasi-solid polymer electrolyte for stable lithium metal batteries
Zhu, Shuangshuang
Niu, Wei
Yu, Junli
Li, Zhenxi
Gao, Shilun
Cheng, Tianhui
Guo, Ruijie
Yang, Dandan
Yang, Huabin
Cao, Peng-Fei
JOURNAL OF ENERGY CHEMISTRY, 2025, 107 : 671 - 681
[16] Competitive coordination of Na plus to "rescue" lithium-ion mobility in zwitterionic quasi-solid electrolytes for lithium metal batteries
Zhang, Yating
Zhang, Yanan
Lin, Weiteng
Li, Xuan
Ji, Kemeng
Chen, Mingming
JOURNAL OF ENERGY CHEMISTRY, 2025, 104 : 52 - 61
[17] Solid-state electrolytes based on metal-organic frameworks for enabling high-performance lithium-metal batteries: Fundamentals, progress, and perspectives
Wang, Hongyao
Duan, Song
Zheng, Yun
Qian, Lanting
Liao, Can
Dong, Li
Guo, Huisong
Ma, Chunxiang
Yan, Wei
Zhang, Jiujun
ETRANSPORTATION, 2024, 20
[18] Critical Review of Fluorinated Electrolytes for High-Performance Lithium Metal Batteries
Li, Zhongzhe
Chen, Yufang
Yun, Xiaoru
Gao, Peng
Zheng, Chunman
Xiao, Peitao
ADVANCED FUNCTIONAL MATERIALS, 2023, 33 (32)
[19] A safe quasi-solid electrolyte based on a nanoporous ceramic membrane for high-energy, lithium metal batteries
Pianta, N.
Baldini, A.
Ferrara, C.
Anselmi-Tamburini, U.
Milanese, C.
Mustarelli, P.
Quartarone, E.
ELECTROCHIMICA ACTA, 2019, 320
[20] Quasi-Solid Electrolytes with Flexible Branches and Rigid Skeletons for High-Temperature Li Metal Batteries
Ma, Lanhua
Zhao, Jiwei
Li, Mengjie
Su, Hai
Li, Yong
Liu, Yuansheng
Liu, Hang
Zygadlo-Monikowska, Ewa
Xu, Yunhua
ACS APPLIED MATERIALS & INTERFACES, 2025, 17 (12) : 18206 - 18216

← 1 2 3 4 5 →