Issue 6, 2023

Automated MUltiscale simulation environment

Abstract

Multiscale techniques integrating detailed atomistic information on materials and reactions to predict the performance of heterogeneous catalytic full-scale reactors have been suggested but lack seamless implementation. The largest challenges in the multiscale modeling of reactors can be grouped into two main categories: catalytic complexity and the difference between time and length scales of chemical and transport phenomena. Here we introduce the Automated MUltiscale Simulation Environment AMUSE, a workflow that starts from Density Functional Theory (DFT) data, automates the analysis of the reaction networks through graph theory, prepares it for microkinetic modeling, and subsequently integrates the results into a standard open-source Computational Fluid Dynamics (CFD) code. We demonstrate the capabilities of AMUSE by applying it to the unimolecular iso-propanol dehydrogenation reaction and then, increasing the complexity, to the pre-commercial Pd/In2O3 catalyst employed for the CO2 hydrogenation to methanol. The results show that AMUSE allows the computational investigation of heterogeneous catalytic reactions in a comprehensive way, providing essential information for catalyst design from the atomistic to the reactor scale level.

Graphical abstract: Automated MUltiscale simulation environment

Supplementary files

Article information

Article type
Paper
Submitted
23 Aug 2023
Accepted
05 Nov 2023
First published
07 Nov 2023
This article is Open Access
Creative Commons BY license

Digital Discovery, 2023,2, 1721-1732

Automated MUltiscale simulation environment

A. Sabadell-Rendón, K. Kaźmierczak, S. Morandi, F. Euzenat, D. Curulla-Ferré and N. López, Digital Discovery, 2023, 2, 1721 DOI: 10.1039/D3DD00163F

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