Combined experimental and molecular dynamics investigation of 1D rod-like asphaltene aggregation in toluene-hexane mixture

The aggregation behavior of asphaltene in the toluene-hexane mixture is systematically investigated using experimental techniques such as optical microscopy and Fourier-transform infrared spectroscopy (FTIR) combined with molecular dynamics (MD) simulations. The optical images of various asphaltene concentrations are processed to determine the size of asphaltene aggregates. FTIR is performed within our work in order to understand the formation of aggregates and its interaction with the solvent mixture. MD simulations are employed to achieve atomistic insights into the aggregation behavior of asphaltene. The end-to-end distance of the asphaltene molecule is calculated for various asphaltene concentrations in the toluene-hexane mixture. The dynamical properties of the asphaltene aggregates such as the diffusion coefficient and shear viscosity are calculated. Further, an in-depth analysis of the density contours is performed to probe the clusterization of asphaltene. Thus obtained structural and dynamical properties of the asphaltene aggregates in the toluene-hexane mixture are compared with our experimental findings. Our results thereby highlight the importance of the combined experimental and theoretical study to achieve deeper and better insights into the aggregation behavior of asphaltene in toluene-hexane mixture. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The aggregation behavior of asphaltene in the toluene-hexane mixture was systematically investigated using a combination of experimental techniques and molecular dynamics simulations. The study focused on determining the size of asphaltene aggregates, understanding their formation and interaction with the solvent mixture, and calculating the dynamical properties such as diffusion coefficient and shear viscosity.Comparison with experimental findings highlighted the importance of a combined experimental and theoretical study for deeper insights into asphaltene aggregation behavior.