Li deposition and desolvation with electron transfer at a silicon/propylene-carbonate interface: transition-state and free-energy profiles by large-scale first-principles molecular dynamics

Li deposition and desolvation with electron transfer at a silicon/propylene-carbonate interface: transition-state and free-energy profiles by large-scale first-principles molecular dynamics

We report the result of a large-scale first-principles molecular dynamics simulation under different electric biases performed to understand the charge transfer process coupling with lithium deposition and desolvation processes. We applied the effective screening medium (ESM) method to control the b...

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Veröffentlicht in:Physical chemistry chemical physics : PCCP 2018, Vol.20 (17), p.11586-11591
Hauptverfasser: Ohwaki, Tsukuru, Ozaki, Taisuke, Okuno, Yukihiro, Ikeshoji, Tamio, Imai, Hideto, Otani, Minoru
Format: Artikel
Sprache:eng
Schlagworte:
Bias
Charge transfer
Coupling (molecular)
Deposition
Electrodes
Electron transfer
First principles
Lithium
Molecular chains
Molecular dynamics
Propylene
Silicon
Solvation
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Zusammenfassung:We report the result of a large-scale first-principles molecular dynamics simulation under different electric biases performed to understand the charge transfer process coupling with lithium deposition and desolvation processes. We applied the effective screening medium (ESM) method to control the bias across the electrode/solution interface, and simulated a series of Li de-solvation and Li-deposition reactions occurring under the bias. Solvated Li+ in the bulk propylene carbonate migrates to the Si electrode surface and gradually de-solvates through the transition state. Introducing the blue-moon ensemble method, we determined the possible structures and activation energies for the transition states.
ISSN:1463-9076
1463-9084
DOI:10.1039/c7cp08569a