Size-transferable prediction of excited state properties for molecular assemblies with machine-learned exciton model

20 December 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Computational modeling of the excited states of molecular aggregates faces significant computational challenges and size heterogeneity. Current machine learning (ML) models, typically trained on specific-sized aggregates, struggle with scalability. We found that the exciton model Hamiltonian of large aggregates can be decomposed into dimer pairs, allowing an ML model trained on dimers to reconstruct Hamiltonians for aggregates of any size. We trained an ML model on perylene dimer exciton Hamiltonians using quantum chemistry descriptors to resolve phase correction issues. Our model accurately predicted excitation energies and oscillator strengths in perylene trimers and tetramers, and analyzed the size-dependent optical bandgap in aggregates with up to 50 monomers, revealing quantum dot-like confinement effects. Future work will explore transferability across different monomers to predict optical properties in heterogeneous assemblies.

Keywords

polycyclic aromatic hydrocarbon aggregate
PAH aggregate
Frenkel exciton model
multiscale-modeling

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Supporting information of: Size-transferable prediction of excited state properties for molecular assemblies with machine-learned exciton model
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