Atomistic-to-Meso Multi-Scale Data-Driven Graph Surrogate Modeling of Dislocation Glide
From their birth in the manufacturing process, materials inherently contain defects that affect the mechanical behavior across multiple length and time-scales, including vacancies, dislocations, voids and cracks. Understanding, modeling, and real-time simulation of the underlying stochastic micro-st...
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Zusammenfassung: | From their birth in the manufacturing process, materials inherently contain
defects that affect the mechanical behavior across multiple length and
time-scales, including vacancies, dislocations, voids and cracks.
Understanding, modeling, and real-time simulation of the underlying stochastic
micro-structure defect evolution is therefore vital towards multi-scale
coupling and propagating numerous sources of uncertainty from atomistic to
eventually aging continuum mechanics. We develop a graph-based surrogate model
of dislocation glide for computation of dislocation mobility. We model an edge
dislocation as a random walker, jumping between neighboring nodes of a graph
following a Poisson stochastic process. The network representation functions as
a coarse-graining of a molecular dynamics simulation that provides dislocation
trajectories for an empirical computation of jump rates. With this
construction, we recover the original atomistic mobility estimates, with
remarkable computational speed-up and accuracy. Furthermore, the underlying
stochastic process provides the statistics of dislocation mobility associated
to the original molecular dynamics simulation, allowing an efficient
propagation of material parameters and uncertainties across the scales. |
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DOI: | 10.48550/arxiv.2012.05223 |