Periodic Potential for Point Defects in a 2D Hexagonal Colloidal Lattice
Abstract
We explore the statistical nature of point defects in a two-dimensional hexagonal colloidal crystal from the perspective of stochastic dynamics. Starting from the experimentally recorded trajectories of time series, the underlying drifting forces along with the diffusion matrix from thermal fluctuations are extracted. We then employ a deposition in which the deterministic terms are split into diffusive and transverse components under a stochastic potential with the lattice periodicity to uncover the dynamic landscape as well as the transverse matrix, two key structures from limited ranges of measurements. The analysis elucidates some fundamental dichotomy between mono-point and di-point defects of paired vacancies or interstitials. Having large transverse magnitude, the second class of defects are likely to break the detailed balance, Such a scenario was attributed to the root cause of lattice melting by experimental observations. The constructed potential can in turn facilitate large-scale simulation for the ongoing research.