Interfacially Induced Cascading Failure in Graphite-Silicon Composite Anodes: Article No. 1801007

Chunmei Ban, Simon Hafner, Arthur Cresce, Markus Groner, Kang Xu, Seoung-Bum Son, Lei Cao, Taeho Yoon, Jun Liu

Research output: Contribution to journalArticlepeer-review

70 Scopus Citations

Abstract

Silicon (Si) has been well recognized as a promising candidate to replace graphite because of its earth abundance and high-capacity storage, but its large volume changes upon lithiation/delithiation and the consequential material fracturing, loss of electrical contact, and over-consumption of the electrolyte prevent its full application. As a countermeasure for rapid capacity decay, a composite electrode of graphite and Si has been adopted by accommodating Si nanoparticles in a graphite matrix. Such an approach, which involves two materials that interact electrochemically with lithium in the electrode, necessitates an analytical methodology to determine the individual electrochemical behavior of each active material. In this work, a methodology comprising differential plots and integral calculus is established to analyze the complicated interplay among the two active batteries and investigate the failure mechanism underlying capacity fade in the blend electrode. To address performance deficiencies identified by this methodology, an aluminum alkoxide (alucone) surface-modification strategy is demonstrated to stabilize the structure and electrochemical performance of the Silicon (Si) has been well recognized as a promising candidate to replace graphite because of its earth abundance and high-capacity storage, but its large volume changes upon lithiation/delithiation and the consequential material fracturing, loss of electrical contact, and over-consumption of the electrolyte prevent its full application. As a countermeasure for rapid capacity decay, a composite
Original languageAmerican English
Number of pages8
JournalAdvanced Science
Volume6
Issue number3
DOIs
StatePublished - 2019

NREL Publication Number

  • NREL/JA-5900-71599

Keywords

  • energy storage
  • lithium-ion batteries
  • molecular layer deposition
  • silicon anodes
  • solid electrolyte interphase

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