Understanding LIB Battery Electrodes Through Classical Electrochemical Interface Theory

G. Michael Carroll, Gabriel Veith

Research output: NRELPoster

Abstract

Classical models of the electrochemical interface can be applied to complex and dynamic electrodes to understand important mechanisms that are relevant to device-level phenomena like calendar aging or cycle life. Here, we show that negative alloy electrodes with wide electrochemical windows cannot be assumed to have static interfaces throughout all states of charge. Under high states of charge, the interface -including the solid electrolyte interphase - has characteristics that resemble a highly polarized electrode far from the point of zero charge. Under these conditions, the interface can be understood through the Helmholtz model. At lower states of charge, the interface capacitance decreases and the space charge layer length increases. This transformation resembles a metal electrode approaching the point of zero charge which is understood through the Gouy-Chapman-Stern-Grahame model of the electrochemical interface. This transformation happens at both silicon and carbon-coated silicon interfaces. From voltage-limited cycling experiments, in the limit of the diffuse double layer, the silicon electrode impedance rises significantly in the first few cycles. This rise is related to the continuous electrochemical reduction of electrolyte components from an interface that is not electronically screened from the electrolyte. In other words, an electrode interface for batteries should resemble a 'Helmholtz-like' structure.
Original languageAmerican English
PublisherNational Renewable Energy Laboratory (NREL)
Number of pages1
StatePublished - 2024

Publication series

NamePresented at the Electrochemistry Gordon Research Conference (GRC), 7-12 January 2024, Ventura, California

NREL Publication Number

  • NREL/PO-5900-88450

Keywords

  • anode
  • electrochemical energy storage
  • lithium ion battery
  • silicon

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