Steepest-Entropy-Ascent Framework for Predicting Arsenic Adsorption on Graphene Oxide Surfaces -- A Case Study

The steepest-entropy-ascent quantum thermodynamics (SEAQT) framework is employed to describe the adsorption process of arsenic (V) onto graphene oxide both in and out of equilibrium. The steepest-entropy-ascent principle is used to derive a non-equilibrium equation of motion applicable to a system composed of five species: water, arsenic, two functional groups of graphene oxide, and hydrogen ions. The equation of motion is solved using the system's energy eigenstructure. This eigenstructure is constructed with the Replica-Exchange Wang-Landau algorithm and used to train an artificial neural network that predicts the energy eigenstructure for dilute arsenic concentrations in the range of groundwater contamination. For a specified initial pH and specified initial concentrations of Ar and graphene oxide, the framework predicts arsenic adsorption capacity and the stable equilibrium arsenic concentration. Equilibrium results match well with equilibrium experimental data, demonstrating the efficacy of this framework for describing the adsorption process. Finally, the model is used to predict non-equilibrium adsorption behavior and the influence of solution pH upon arsenic removal efficiency.
Comment: 17 pages, 13 figures