Publications Details
Designing Catalysts for Dehydrogenation of Methane for Reducing Greenhouse Gas during Natural Gas Extraction
Catalytic conversion of methane (CH 4) into useful products is critical for maximizing the utility of natural gas output and for reducing green house gas release associated with flaring (burning off CH4 at natural gas extraction sites). One particular useful technique is methane dry reforming (DRM), which involves the chemical reaction of CH4 with carbon dioxide (CO2) to generate carbon monoxide (CO), hydrogen gas (H2), and subsequently other useful products. New and improved catalysts are required to facilitate efficient dry methane reforming. In this report, we apply the Density Functional Theory (DFT) computational technique to investigate a catalyst consisting of small nickel clusters (Ni n , n < 10) on ceria (Ce02 (111) surfaces) support. One main thrust of this project is to study the initial CH4 and CO2 reactions with the catalyst. We find that CH4 exhibits barrierless reactive adsorption on to the catalyst. In order words, this step is likely not the rate-determining step. A second thrust is to perform detailed studies of the catalyst itself and examine the role of oxygen vacancies. Using a specific DFT method and a hypothesis about the absence of the Ce(III) redox state, we obtain predictions about oxygen vacancies in good agreement with experimental observations.