Date of Award

Fall 2022

Document Type

Dissertation

Degree Name

Doctor of Philosophy (PhD)

Department

Chemistry

First Advisor

Mayer, James

Abstract

Iron carbide catalysts have been used for nearly 100 years in the Fischer-Tropsch process (FTP), yet the atomic nature of the active site(s) for H2 and CO have not been fully characterized. The FTP has recently gained interest as a method for the sustainable production of aviation fuels; however, this process suffers from limited product selectivity. A better understanding of the active site(s) could allow for more rational design of iron carbide catalysts, where changes in active site structure(s) could be correlated with catalyst activity. Here, we present the synthesis, characterization, and catalysis by a well-defined dodecylamine-capped colloidal iron carbide (DDA-FexC) nanoparticle (NP) system. This colloidal NP system is amenable to solution phase reactivity studies, spectroscopic measurements, and catalysis towards olefin hydrogenation and carbon monoxide hydrogenation at mild conditions. The tandem use of x-ray and FTIR spectroscopies along with density functional theory (DFT) calculations and molecular dynamic simulations enabled the identification of the structures of adsorbed hydrogen (Hads) and carbon monoxide (COads) over these DDA-FexC NPs. 57Fe Nuclear resonant vibrational spectroscopy revealed a Fe-C vibration for COads consistent with terminally bound CO, as supported by DFT calculations. FTIR revealed a distribution of *C-D vibrations for NPs treated with D2, consistent with adsorption over surface carbide sites supported by DFT calculations. Extended x-ray absorption fine structure (EXAFS) measurements of DDA-FexC NPs treated with H2 and CO showed measurable increases in Fe-Fe and Fe-C bond lengths that varied with coverage. The experimentally measured vibrational energies are used to validate the active site structures generated by DFT calculations and molecular dynamics. These results demonstrate the powerful combination of experiment and theory to better understand an elusive catalytic system and may aid in the rational development of future iron carbide catalysts.

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