English

Multi-objective optimization for targeted self-assembly among competing polymorphs

Soft Condensed Matter 2025-05-08 v3 Materials Science

Abstract

Most approaches for designing self-assembled materials focus on the thermodynamic stability of a target structure or crystal polymorph. Yet in practice, the outcome of a self-assembly process is often controlled by kinetic pathways. Here we present an efficient machine learning-guided design algorithm to identify globally optimal interaction potentials that maximize both the thermodynamic yield and kinetic accessibility of a target polymorph. We show that optimal potentials exist along a Pareto front, indicating the possibility of a trade-off between the thermodynamic and kinetic objectives. Although the extent of this trade-off depends on the target polymorph and the assembly conditions, we generically find that the trade-off arises from a competition among alternative polymorphs: The most kinetically optimal potentials, which favor the target polymorph on short timescales, tend to stabilize a competing polymorph at longer times. Our work establishes a general-purpose approach for multi-objective self-assembly optimization, reveals fundamental trade-offs between crystallization speed and defect formation in the presence of competing polymorphs, and suggests guiding principles for materials design algorithms that optimize for kinetic accessibility.

Keywords

Cite

@article{arxiv.2401.11234,
  title  = {Multi-objective optimization for targeted self-assembly among competing polymorphs},
  author = {Sambarta Chatterjee and William M. Jacobs},
  journal= {arXiv preprint arXiv:2401.11234},
  year   = {2025}
}
R2 v1 2026-06-28T14:22:28.236Z