Issue 36, 2023

Machine learning approaches for the optimization of packing densities in granular matter

Abstract

The fundamental question of how densely granular matter can pack and how this density depends on the shape of the constituent particles has been a longstanding scientific problem. Previous work has mainly focused on empirical approaches based on simulations or mean-field theory to investigate the effect of shape variation on the resulting packing densities, focusing on a small set of pre-defined shapes like dimers, ellipsoids, and spherocylinders. Here we discuss how machine learning methods can support the search for optimally dense packing shapes in a high-dimensional shape space. We apply dimensional reduction and regression techniques based on random forests and neural networks to find novel dense packing shapes by numerical optimization. Moreover, an investigation of the regression function in the dimensionally reduced shape representation allows us to identify directions in the packing density landscape that lead to a strongly non-monotonic variation of the packing density. The predictions obtained by machine learning are compared with packing simulations. Our approach can be more widely applied to optimize the properties of granular matter by varying the shape of its constituent particles.

Graphical abstract: Machine learning approaches for the optimization of packing densities in granular matter

Article information

Article type
Paper
Submitted
28 Oct 2022
Accepted
18 Jul 2023
First published
20 Jul 2023
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2023,19, 6875-6884

Machine learning approaches for the optimization of packing densities in granular matter

A. Baule, E. Kurban, K. Liu and H. A. Makse, Soft Matter, 2023, 19, 6875 DOI: 10.1039/D2SM01430K

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