First-principles-informed energy span and microkinetic analysis of ethanol catalytic conversion to 1,3-butadiene on MgO
Journal article, 2021

Kinetic modeling of single-step catalytic conversion of ethanol to 1,3-butadiene is necessary to inform accurate process design. This paper uses first-principles-informed energy span and microkinetic analysis to explore the reaction free energy landscapes and kinetic limitations of competing reaction pathways on a MgO (100) step-edge. Previous studies suggested mechanisms proceeding via both dehydrogenation and dehydration of ethanol, and highlighted sensitivity to conditions and catalyst composition. Here, we use the energy span concept to characterize the theoretical maximum turnover and degree of turnover frequency control for states in each reaction pathway, finding the dehydration route to be less active for 1,3-butadiene, and suggesting rate-determining states in the dehydrogenation, dehydration, and condensation steps. The influence of temperature on the relative rate contribution of each state is quantified and explained through the varying temperature sensitivity of the free energy landscape. A microkinetic model is developed to explore competition between pathways, interaction with gas-phase species, and surface coverage limitations. This suggests that the turnover may be significantly lower than predicted solely based on energetics. Turnover frequency determining states found to have high surface coverage include adsorbed ethanol and two longer, oxygenated hydrocarbons. The combined energy span and microkinetic analysis permits investigation of a complex system from two perspectives and helps elucidate conflicting observations of rate determining steps and product distribution by considering both energetic and kinetic limitations. The impact of uncertainty in the energy landscape is quantified using a correlated error model. While the range of predictions is large, the average performance and trends are similar.

Author

Astrid Boje

Chalmers, Physics, Chemical Physics

William E. Taifan

Lehigh University

Henrik Ström

Chalmers, Mechanics and Maritime Sciences (M2), Fluid Dynamics

Tomas Bucko

Slovak Academy of Sciences

Comenius University in Bratislava

Jonas Baltrusaitis

Lehigh University

Anders Hellman

Competence Centre for Catalysis (KCK)

Chalmers, Physics, Chemical Physics

Catalysis Science and Technology

2044-4753 (ISSN) 2044-4761 (eISSN)

Vol. 11 20 6682-6694

Subject Categories

Other Engineering and Technologies not elsewhere specified

Other Chemical Engineering

Other Physics Topics

DOI

10.1039/d1cy00419k

More information

Latest update

5/26/2023