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Predicting optical spectra for optoelectronic polymers using coarse-grained models and recurrent neural networks

Lena Simine, Thomas C. Allen, Peter J. Rossky

2020Proceedings of the National Academy of Sciences51 citationsDOIOpen Access PDF

Abstract

Coarse-grained modeling of conjugated polymers has become an increasingly popular route to investigate the physics of organic optoelectronic materials. While ultraviolet (UV)-vis spectroscopy remains one of the key experimental methods for the interrogation of these materials, a rigorous bridge between simulated coarse-grained structures and spectroscopy has not been established. Here, we address this challenge by developing a method that can predict spectra of conjugated polymers directly from coarse-grained representations while avoiding repetitive procedures such as ad hoc back-mapping from coarse-grained to atomistic representations followed by spectral computation using quantum chemistry. Our approach is based on a generative deep-learning model: the long-short-term memory recurrent neural network (LSTM-RNN). The latter is suggested by the apparent similarity between natural languages and the mathematical structure of perturbative expansions of, in our case, excited-state energies perturbed by conformational fluctuations. We also use this model to explore the level of sensitivity of spectra to the coarse-grained representation back-mapping protocol. Our approach presents a tool uniquely suited for improving postsimulation analysis protocols, as well as, potentially, for including spectral data as input in the refinement of coarse-grained potentials.

Topics & Concepts

Computer scienceRepresentation (politics)Artificial neural networkSpectroscopySimilarity (geometry)Spectral lineBiological systemArtificial intelligencePhysicsQuantum mechanicsLawPolitical sciencePoliticsImage (mathematics)BiologyMachine Learning in Materials ScienceAdvanced Memory and Neural ComputingOrganic Electronics and Photovoltaics