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    A Simultaneous Multiscale and Multiphysics Model and Numerical Implementation of a Core-Shell Model for Lithium-Ion Full-Cell Batteries

    Source: Journal of Applied Mechanics:;2019:;volume( 086 ):;issue: 004::page 41005
    Author:
    Liu, Binghe
    ,
    Wang, Xu
    ,
    Chen, Hao-Sen
    ,
    Chen, Sen
    ,
    Yang, Hongxin
    ,
    Xu, Jun
    ,
    Jiang, Hanqing
    ,
    Fang, Dai-Ning
    DOI: 10.1115/1.4042432
    Publisher: The American Society of Mechanical Engineers (ASME)
    Abstract: The increasing significance on the development of high-performance lithium-ion (Li-ion) batteries is calling for new battery materials, theoretical models, and simulation tools. Lithiation-induced deformation in electrodes calls attention to study the multiphysics coupling between mechanics and electrochemistry. In this paper, a simultaneous multiscale and multiphysics model to study the coupled electrochemistry and mechanics in the continuum battery cell level and the microscale particle level was developed and implemented in comsolmultiphysics. In the continuum scale, the porous electrode theory and the classical mechanics model were applied. In the microscale, the specific particle structure has been incorporated into the model. This model was demonstrated to study the effects of mechanical constraints, charging rate, and silicon/C ratio, on the electrochemical performance. This model provides a powerful tool to perform simultaneous multiscale and multiphysics design on Li-ion batteries, from the particle level to full-cell level.
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      A Simultaneous Multiscale and Multiphysics Model and Numerical Implementation of a Core-Shell Model for Lithium-Ion Full-Cell Batteries

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    http://yetl.yabesh.ir/yetl1/handle/yetl/4255703
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    contributor authorLiu, Binghe
    contributor authorWang, Xu
    contributor authorChen, Hao-Sen
    contributor authorChen, Sen
    contributor authorYang, Hongxin
    contributor authorXu, Jun
    contributor authorJiang, Hanqing
    contributor authorFang, Dai-Ning
    date accessioned2019-03-17T09:49:46Z
    date available2019-03-17T09:49:46Z
    date copyright1/30/2019 12:00:00 AM
    date issued2019
    identifier issn0021-8936
    identifier otherjam_086_04_041005.pdf
    identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4255703
    description abstractThe increasing significance on the development of high-performance lithium-ion (Li-ion) batteries is calling for new battery materials, theoretical models, and simulation tools. Lithiation-induced deformation in electrodes calls attention to study the multiphysics coupling between mechanics and electrochemistry. In this paper, a simultaneous multiscale and multiphysics model to study the coupled electrochemistry and mechanics in the continuum battery cell level and the microscale particle level was developed and implemented in comsolmultiphysics. In the continuum scale, the porous electrode theory and the classical mechanics model were applied. In the microscale, the specific particle structure has been incorporated into the model. This model was demonstrated to study the effects of mechanical constraints, charging rate, and silicon/C ratio, on the electrochemical performance. This model provides a powerful tool to perform simultaneous multiscale and multiphysics design on Li-ion batteries, from the particle level to full-cell level.
    publisherThe American Society of Mechanical Engineers (ASME)
    titleA Simultaneous Multiscale and Multiphysics Model and Numerical Implementation of a Core-Shell Model for Lithium-Ion Full-Cell Batteries
    typeJournal Paper
    journal volume86
    journal issue4
    journal titleJournal of Applied Mechanics
    identifier doi10.1115/1.4042432
    journal fristpage41005
    journal lastpage041005-12
    treeJournal of Applied Mechanics:;2019:;volume( 086 ):;issue: 004
    contenttypeFulltext
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    DSpace software copyright © 2002-2015  DuraSpace
    نرم افزار کتابخانه دیجیتال "دی اسپیس" فارسی شده توسط یابش برای کتابخانه های ایرانی | تماس با یابش
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