Many-particle limits and non-convergence of dislocation wall pile-ups
Patrick van Meurs

TL;DR
This paper investigates the behavior of one-dimensional two-species particle systems modeling dislocation wall pile-ups, analyzing their many-particle limits and demonstrating conditions for convergence and non-convergence of their gradient flows.
Contribution
It establishes the b3-convergence of particle system energies and the evolutionary convergence of gradient flows under certain conditions, revealing non-convergence in other regimes.
Findings
b3-convergence of particle energies
Evolutionary convergence of gradient flows for large bcln
Non-convergence of gradient flows for small bcln
Abstract
The starting point of our analysis is a class of one-dimensional interacting particle systems with two species. The particles are confined to an interval and exert a nonlocal, repelling force on each other, resulting in a nontrivial equilibrium configuration. This class of particle systems covers the setting of pile-ups of dislocation walls, which is an idealised setup for studying the microscopic origin of several dislocation density models in the literature. Such density models are used to construct constitutive relations in plasticity models. Our aim is to pass to the many-particle limit. The main challenge is the combination of the nonlocal nature of the interactions, the singularity of the interaction potential between particles of the same type, the non-convexity of the the interaction potential between particles of the opposite type, and the interplay between the length-scale…
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