Abstract
We have developed a proof of concept electrode design to covalently graft poly(methyl methacrylate) brushes directly to silicon thin film electrodes via surface-initiated atom transfer radical polymerization. This polymer layer acts as a stable artificial solid electrolyte interface that enables surface passivation despite large volume changes during cycling. Thin polymer layers (75 nm) improve average first cycle coulombic efficiency from 62.4% in bare silicon electrodes to 76.3%. Average first cycle reversible capacity was improved from 3157 to 3935 mAh g−1, and average irreversible capacity was reduced from 2011 to 1020 mAh g−1. Electrochemical impedance spectroscopy performed on silicon electrodes showed that resistance from solid electrolyte interface formation increased from 79 to 1508 Ω in untreated silicon thin films over 26 cycles, while resistance growth was lower – from 98 to 498 Ω – in silicon films functionalized with PMMA brushes. The lower increase suggests enhanced surface passivation and lower electrolyte degradation. This work provides a pathway to develop artificial solid electrolyte interfaces synthesized under controlled reaction conditions.
Highlights
Lithium-based energy storage technologies are attractive given their large cell voltages and power densities
The solid electrolyte interface (SEI) layer synthesized by ATRP ARGET is a dense layer of Poly(methyl methacrylate) (PMMA) brushes tethered at one end to the electrode surface
We have presented facile, functionalization of silicon based electrodes with PMMA brushes as artificial SEI’s via ATRP
Summary
We have developed a proof of concept electrode design to covalently graft poly(methyl methacrylate) brushes directly to silicon thin film electrodes via surface-initiated atom transfer radical polymerization This polymer layer acts as a stable artificial solid electrolyte interface that enables surface passivation despite large volume changes during cycling. The surface-tethered brushes can accommodate the large electrode volume fluctuations silicon undergoes during (de)lithiation and maintain silicon surface passivation The result of this enhanced passivation is decreased additional SEI formation and surface side reactions during cycling, increasing the reversible capacity available toward silicon lithiation. Long term enhanced passivation of silicon is confirmed with potentiostatic electrochemical impedance spectroscopy These findings will guide future development of surface-tethered polymeric artificial solid electrolyte interfaces synthesized via surface-initiated atom transfer radical polymerization
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