Abstract
Silicon electrodes can give high capacity as anodes for lithium-ion batteries. However, there has not been much work quantifying the different contributions to the reversible and irreversible capacities. Here, we report the use of an electrochemical approach – depth of discharge test – to separate the charge-discharge capacities of crystalline silicon electrodes into four contributions: (1) SEI formation, (2) lithium accommodation in carbon and binder, (3) lithiation and delithiation of the Si active material, and (4) capacity loss associated with particle cracking and isolation. We find that the intrinsic coulombic efficiency for the crystalline-to-amorphous transition of Si during initial cycle is about 90%, which is independent of particle size. SEI formation is estimated to be about 10 mAh per square meters of active material surface and scales with BET surface area. Mechanical issues and particle isolation are observed in fully discharged electrode when the amount of binder is less than 20%. Capacity limitation prolongs lifetime of Si electrode, but the overall performance is governed by the coulombic efficiency (CE) during cycle. Low CE is due to continual SEI formation with cycling, increase utilization of Si upon cycling, trapping of Li in the material and mechanical failure of the electrode.
Highlights
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Citing this paper Please note that where the full-text provided on CityU Scholars is the Post-print version, it may differ from the Final Published version
We report the use of an electrochemical approach – depth of discharge test – to separate the charge-discharge capacities of crystalline silicon electrodes into four different contributions: solid electrolyte interphase (SEI) formation, lithium accommodation in carbon and binder, and lithiation and delithiation of the active material, and capacity loss associated with particle cracking and isolation
Summary
Document Version: Final Published version, known as Publisher’s PDF, Publisher’s Final version or Version of Record. Citing this paper Please note that where the full-text provided on CityU Scholars is the Post-print version ( known as Accepted Author Manuscript, Peer-reviewed or Author Final version), it may differ from the Final Published version. Ensure that you check and use the publisher's definitive version for pagination and other details. Links to full text versions (either Published or Post-print) are only available if corresponding publishers allow open access. FOCUS ISSUE OF SELECTED PAPERS FROM IMLB 2016 WITH INVITED PAPERS CELEBRATING 25 YEARS OF LITHIUM ION BATTERIES. Battery and Energy Storage Technologies Laboratory, School of Energy and Environment, City University of Hong Kong, Hong Kong
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