Effects of polymeric binders on the cracking behavior of silicon composite electrodes during electrochemical cycling

Mechanical degradation caused by lithiation/delithiation-induced stress and large volume change is the primary cause of fast capacity fading of silicon (Si)-based electrodes. Although intensive efforts have been devoted to understanding electromechanically induced fractures of electrodes made of Si...

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Bibliographic Details
Published in:Journal of power sources 2019-10, Vol.438 (C), p.226938, Article 226938
Main Authors: Wang, Yikai, Dang, Dingying, Li, Dawei, Hu, Jiazhi, Zhan, Xiaowen, Cheng, Yang-Tse
Format: Article
Language:English
Subjects:
Adhesion
Chemistry
Cracking
Electrochemistry
Energy & Fuels
ENERGY STORAGE
In situ observation
Lithium ion battery
Materials Science
Polymeric binder
Silicon electrode
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Summary:Mechanical degradation caused by lithiation/delithiation-induced stress and large volume change is the primary cause of fast capacity fading of silicon (Si)-based electrodes. Although intensive efforts have been devoted to understanding electromechanically induced fractures of electrodes made of Si alone (e.g., Si particles, Si thin films, and Si wafers), the cracking behavior of Si/polymeric binders/carbon black composite electrodes is unclear and poorly understood. Here, we investigate, by in situ and ex situ techniques, the cracking behavior of Si composite electrodes made with different binders, including polyvinylidene fluoride (PVDF), sodium-alginate (SA), sodium-carboxymethyl cellulose (Na-CMC), and Nafion. We found that extensive cracks form during the 1st delithiation process, which periodically open and close during subsequent lithiation/delithiation cycles at the same locations in the Si composite electrodes made with SA, Na-CMC, and Nafion. In contrast, a significantly fewer number of cracks form in the Si/PVDF electrodes after electrochemical cycling. A possible mechanism is proposed to help understand the effects of binders on the cracking behavior (e.g., crack spacing and island size) of Si composite electrodes. We also suggest possible approaches, including reducing the electrode thickness, patterning electrodes, and using highly recoverable binders, to inhibit cracks and improve the mechanical integrity of Si composite electrodes. •In situ observations of the cracking behavior of Si composite electrodes during cycling.•Cracks open/close at the same locations during delithiation/lithiation.•Understanding the effects of binders on the cracking behavior of Si composite electrodes.•Strategies to inhibit cracks in Si composite electrodes.
ISSN:0378-7753
1873-2755
DOI:10.1016/j.jpowsour.2019.226938