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Area of Science:

  • Electrochemistry
  • Computational Materials Science
  • Multiscale Modeling

Background:

  • Electrochemical systems are vital for technologies like batteries and electronics.
  • A significant scale gap exists between atomic-level simulations (nanoseconds/nanometers) and experiments (seconds/micrometers).
  • This discrepancy hinders direct correlation between computational and experimental findings.

Purpose of the Study:

  • To develop an equivalent simulation setup bridging the scale gap in electrochemical experiments.
  • To exclude microstructure effects and enable correlation between atomistic and continuum scales.
  • To provide a model for forecasting experimental dynamics and steady-state transitions.

Main Methods:

  • Utilizing a coarse-grained framework to establish an equivalent simulation setup.
  • Adjusting parameters for equivalent length scale (lEQ), diffusivity (DEQ), and voltage (VEQ).
  • Focusing on the solid-electrolyte interface to exclude microstructure effects.

Main Results:

  • The developed equivalent paradigm successfully matches time scales for concentration gradient formation and relaxation.
  • Atomistic equivalent simulations correlate with continuum-scale experimental observations.
  • The model allows exploration of inter-ionic events over extended periods.

Conclusions:

  • The coarse-grained framework effectively bridges the scale gap in electrochemical simulations.
  • The adjusted parameters (lEQ, DEQ, VEQ) enable multi-scale correlation.
  • This approach offers valuable insights for predicting experimental behavior and operational transitions.