Tracking the Chemical Evolution of Iodine Species Using Recurrent Neural Networks | Zendy

Jenna A. Bilbrey | Zendy; Carlos Ortiz Marrero | Zendy; Michel Sassi | Zendy; Andrew M. Ritzmann | Zendy; Neil J. Henson | Zendy; Malachi Schram | Zendy

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Tracking the Chemical Evolution of Iodine Species Using Recurrent Neural Networks

Author(s) -

Jenna A. Bilbrey,

Carlos Ortiz Marrero,

Michel Sassi,

Andrew M. Ritzmann,

Neil J. Henson,

Malachi Schram

Publication year - 2020

Publication title -

acs omega

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.779

H-Index - 40

ISSN - 2470-1343

DOI - 10.1021/acsomega.9b04104

Subject(s) - recurrent neural network , initialization , robustness (evolution) , computer science , artificial neural network , artificial intelligence , training set , tracking (education) , synthetic data , machine learning , chemistry , biochemistry , gene , programming language , psychology , pedagogy

We apply recurrent neural networks (RNNs) to predict the time evolution of the concentration profile of multiple species resulting from a set of interconnected chemical reactions. As a proof of concept of our approach, RNNs were trained on a synthetic dataset generated by solving the kinetic equations of a system of aqueous inorganic iodine reactions that can follow after nuclear reactor accidents. We examine the minimum dataset necessary to obtain accurate predictions and explore the ability of RNNs to interpolate and extrapolate when exposed to previously unseen data. We also investigate the limits of our RNN by evaluating the robustness of the training initialization on our dataset.

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