Approximating the dynamical evolution of systems of strongly-interacting overdamped particles

TL;DR

This paper introduces collective-move Monte Carlo algorithms that better approximate the overdamped dynamics of strongly-interacting nanoscale particles, addressing limitations of traditional single-particle moves in capturing collective relaxation modes.

Contribution

It proposes a novel collective-move Monte Carlo method that explicitly links particles based on energy changes to improve dynamical fidelity in simulations.

Findings

Collective moves better capture cluster self-diffusion.

Dynamic linking criteria outperform static ones.

Enhanced simulation efficiency for self-assembling systems.

Abstract

We describe collective-move Monte Carlo algorithms designed to approximate the overdamped dynamics of self-assembling nanoscale components equipped with strong, short-ranged and anisotropic interactions. Conventional Monte Carlo simulations comprise sequential moves of single particles, proposed and accepted so as to satisfy detailed balance. Under certain circumstances such simulations provide an approximation of overdamped dynamics, but the accuracy of this approximation can be poor if e.g. particle-particle interactions vary strongly with distance or angle. The twin requirements of simulation efficiency (trial moves of appreciable scale are needed to ensure reasonable sampling) and dynamical fidelity (true in the limit of vanishingly small trial moves) then become irreconcilable. As a result, single-particle moves can underrepresent important collective modes of relaxation, such as self-diffusion of particle clusters. However, one way of using Monte Carlo simulation to mimic real collective modes of motion, retaining the ability to make trial moves of reasonable scale, is to make explicit moves of collections of particles. We will outline ways of doing so by iteratively linking particles to their environment. Linking criteria can be static, conditioned upon properties of the current state of a system, or dynamic, conditioned upon energy changes resulting from trial virtual moves of particles. We argue that the latter protocol is better-suited to approximating real dynamics.