# Probabilistic inverse design for self assembling materials

**Authors:** R. B. Jadrich, B. A. Lindquist, and T. M. Truskett

arXiv: 1702.05021 · 2017-09-08

## TL;DR

This paper demonstrates a machine learning-based inverse design method to discover interparticle interactions that enable self-assembly of complex nanostructures, including novel potentials for specific morphologies.

## Contribution

It evaluates the robustness of a recent inverse design strategy by applying it to various microstructures and discovering new interparticle potentials for self-assembly.

## Key findings

- Successfully designed isotropic pair potentials for diverse structures
- Discovered potentials capable of stabilizing previously unachievable morphologies
- Demonstrated advantages of the inverse design approach in flexibility and robustness

## Abstract

One emerging approach for the fabrication of complex architectures on the nanoscale is to utilize particles customized to intrinsically self-assemble into a desired structure. Inverse methods of statistical mechanics have proven particularly effective for the discovery of interparticle interactions suitable for this aim. Here we evaluate the generality and robustness of a recently introduced inverse design strategy [Lindquist et al., J. Chem. Phys. 145, 111101 (2016)] by applying this simulated-based, machine learning method to optimize for interparticle interactions that self-assemble particles into a variety of complex microstructures: cluster fluids, porous mesophases, and crystalline lattices. Using the method, we discover isotropic pair interactions that lead to self-assembly of each of the desired morphologies, including several types of potentials that were not previously understood to be capable of stabilizing such systems. One such pair potential led to assembly of the highly asymmetric truncated trihexagonal lattice and another produced a fluid containing spherical voids, or pores, of designed size via purely repulsive interactions. Through these examples, we demonstrate several advantages inherent to this particular design approach including the use of a parametrized functional form for the optimized interparticle interactions, the ability to constrain the range of said parameters, and compatibility of the inverse design strategy with a variety of simulation protocols (e.g., positional restraints).

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1702.05021/full.md

## References

70 references — full list in the complete paper: https://tomesphere.com/paper/1702.05021/full.md

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Source: https://tomesphere.com/paper/1702.05021