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Prediction of Self-Diffusion in Binary Fluid Mixtures Using Artificial Neural Networks.

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Artificial neural networks (ANNs) accurately predict self-diffusion constants in binary fluid mixtures. This approach effectively models complex behaviors, including those caused by hydrogen bonding, with high precision.

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Area of Science:

  • Chemical Engineering
  • Computational Chemistry
  • Physical Chemistry

Background:

  • Predicting self-diffusion constants in binary fluid mixtures is crucial for process design.
  • Complex intermolecular interactions, such as hydrogen bonding, can lead to non-linear diffusive behavior, challenging traditional models.

Purpose of the Study:

  • To develop accurate artificial neural network (ANN) models for predicting self-diffusion constants in binary fluid mixtures.
  • To incorporate intermolecular interaction strengths, specifically self- and binary association energies, as input features for enhanced model performance.

Main Methods:

  • Trained ANNs on an experimental database of 4328 self-diffusion constants from 131 mixtures.
  • Calculated self- and binary association energies to quantify intermolecular interactions.
  • Employed forward input feature selection to identify key predictive properties.

Main Results:

  • Developed a generalized ANN model with an average absolute deviation of 4.1%.
  • Demonstrated the importance of critical properties and self-association energies in predicting diffusion.
  • Showcased accurate predictions for mixtures with strong hydrogen bonding and under extreme pressure changes.

Conclusions:

  • ANNs provide a robust and accurate method for predicting self-diffusion constants in binary fluid mixtures.
  • Intermolecular interaction energies are vital inputs for capturing complex diffusive behaviors.
  • The developed ANN models show broad applicability across diverse fluid mixtures and conditions.