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Updated: Oct 8, 2025

Bioelectric Analyses of an Osseointegrated Intelligent Implant Design System for Amputees
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On chain models for contact electrification.

Javier E Hasbun1, Lok C Lew Yan Voon1, Morten Willatzen2,3,4

  • 1Physics, University of West Georgia, 1601 Maple St., Carrollton, GA 30118, United States of America.

Journal of Physics. Condensed Matter : an Institute of Physics Journal
|January 4, 2022
PubMed
Summary
This summary is machine-generated.

This study presents an analytical model for atomic charge dynamics, revealing similar behavior with and without electron interactions. The model extends to alloy systems and contact electrification, exploring the impact of transfer elements.

Keywords:
atomic chaincharge dynamicscontact electrificationtight-binding model

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Area of Science:

  • Condensed matter physics
  • Quantum chemistry
  • Materials science

Background:

  • Understanding charge dynamics in atomic systems is crucial for developing novel electronic materials.
  • Asymmetric hopping terms and electron interactions significantly influence charge transport.
  • Contact electrification is a fundamental phenomenon in tribology and materials science.

Purpose of the Study:

  • To develop an exact analytical model for charge dynamics in atomic chains with asymmetric hopping.
  • To investigate the influence of electron interactions on charge dynamics.
  • To extend the model to alloy systems and analyze contact electrification between atomic chains.

Main Methods:

  • Exact analytical modeling of charge dynamics.
  • Numerical simulations to validate analytical results.
  • Extension of the atomic chain model to a two-atom-per-cell system (perfect alloy).
  • Application of the extended model to contact electrification scenarios.

Main Results:

  • The analytical and numerical results demonstrate consistent charge dynamics, both with and without electron interactions.
  • The model successfully captures the behavior of extended systems, including perfect alloys.
  • Analysis of contact electrification reveals the effect of varying the contact transfer matrix element magnitude.

Conclusions:

  • The developed analytical model provides a robust framework for studying charge dynamics in asymmetric atomic chains.
  • Electron interactions do not fundamentally alter the observed charge dynamics in this model.
  • The extended model offers insights into charge transfer mechanisms during contact electrification in material interfaces.