Phase-field modeling of planar interface electrodeposition in lithium-metal batteries

被引:11
|
作者
Arguello, Marcos Exequiel [1 ,2 ]
Gumulya, Monica [3 ]
Derksen, Jos [2 ]
Utikar, Ranjeet [1 ]
Calo, Victor Manuel [4 ]
机构
[1] Curtin Univ, WA Sch Mines Mineral Energy & Chem Engn, POB U1987, Perth, WA 6845, Australia
[2] Univ Aberdeen, Sch Engn, Elphinstone Rd, Aberdeen AB24 3UE, Scotland
[3] Curtin Univ, Sch Populat Hlth, Occupat Environm & Safety, POB U1987, Perth, WA 6845, Australia
[4] Curtin Univ, Sch Elect Engn Comp & Math Sci, POB U1987, Perth, WA 6845, Australia
来源
JOURNAL OF ENERGY STORAGE | 2022年 / 50卷
关键词
Phase-field modeling; Electrodeposition; Li-metal battery; Finite element method; Interface thickness; MATHEMATICAL-MODEL; DENDRITE GROWTH; SIMULATIONS; ENERGY; KINETICS; ANODES;
D O I
10.1016/j.est.2022.104627
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
This paper presents a detailed description of phase-field models of electrodeposition in lithium-anode batteries, along with underlying assumptions and parameters commonly employed. We simulate the coupled electrochemical interactions during a battery charge cycle using finite elements on open-source packages, allowing for parallel computation and time step adaptivity. We compare conventional free energy and grand canonical formulations. We obtain agreement between 1D phase-field simulations and the theoretical Faradic reaction kinetics. We study the mesh-induced errors through spatial convergence analysis. These simulations results set the groundwork for 2D and 3D simulations of dendritic metal electrodeposition in batteries.
引用
收藏
页数:13
相关论文
共 50 条
  • [31] A Liquid/Liquid Electrolyte Interface that Inhibits Corrosion and Dendrite Growth of Lithium in Lithium-Metal Batteries
    He, Xiaofeng
    Liu, Xiao
    Han, Qing
    Zhang, Peng
    Song, Xiaosheng
    Zhao, Yong
    ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2020, 59 (16) : 6397 - 6405
  • [32] Isolated metallic lithium formation in lithium-metal batteries
    Zhang, Jin
    Chadwick, Alexander F.
    Voorhees, Peter W.
    CELL REPORTS PHYSICAL SCIENCE, 2025, 6 (01):
  • [33] Phase-field simulation of magnesium-metal anode interface growth in different electrolytes during electrodeposition
    Wang, Jiachen
    Hou, Hua
    Zhao, Yuhong
    JOURNAL OF ENERGY STORAGE, 2024, 87
  • [34] Mesoscale Phase-Field Modeling of Charge Transport in Nanocomposite Electrodes for Lithium-Ion Batteries
    Hu, Shenyang
    Li, Yulan
    Rosso, Kevin M.
    Sushko, Maria L.
    JOURNAL OF PHYSICAL CHEMISTRY C, 2013, 117 (01): : 28 - 40
  • [35] Understanding electro-mechanical-thermal coupling in solid-state lithium metal batteries via phase-field modeling
    Zhe-Tao Sun
    Shou-Hang Bo
    Journal of Materials Research, 2022, 37 : 3130 - 3145
  • [36] Understanding electro-mechanical-thermal coupling in solid-state lithium metal batteries via phase-field modeling
    Sun, Zhe-Tao
    Bo, Shou-Hang
    JOURNAL OF MATERIALS RESEARCH, 2022, 37 (19) : 3130 - 3145
  • [37] Phase-field modeling of dynamical interface phenomena in fluids
    Ala-Nissila, T
    Majaniemi, S
    Elder, K
    NOVEL METHODS IN SOFT MATTER SIMULATIONS, 2004, 640 : 357 - 388
  • [38] Thermoresponsive Electrolytes for Safe Lithium-Metal Batteries
    Jiang, Feng-Ni
    Cheng, Xin-Bing
    Yang, Shi-Jie
    Xie, Jin
    Yuan, Hong
    Liu, Lei
    Huang, Jia-Qi
    Zhang, Qiang
    ADVANCED MATERIALS, 2023, 35 (12)
  • [39] LITHIUM-METAL SULFIDE BATTERIES FOR LOAD LEVELING
    CHILENSKAS, AA
    FORNEK, TE
    BATTLES, JE
    STEUENBERG, RK
    JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1977, 124 (08) : C278 - C278
  • [40] DEVELOPMENT OF LITHIUM-METAL SULFIDE BATTERIES.
    Anon
    1978,
12345