Browsing by Author "Romo, Joelle E."

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The effect of solvent polarity on autocatalytic furfural production confirmed by multivariate statistical analysis
(2019-10) Romo, Joelle E.; Miller, Kyle C.; Sundsted, Tara L.; Job, Adam L.; Hoo, Karlene A.; Wettstein, Stephanie G.
Autocatalytic dehydration of xylose to furfural was studied in pure aqueous and monophasic organic/water mixtures to determine the effect reaction media and conditions have on conversion and yield. This study identified that the severity (Ro) of the reaction and polarity, as determined by the Hansen Solubility Parameter, δP, strongly correlate with xylose conversion and furfural yield. Increasing the Ro and δP increased both conversion and yield in pure aqueous and organic/water mixtures of sulfolane, γ‐butyrolactone, γ‐valerolactone, γ‐hexalactone, and tetrahydrofuran. Additionally, it was found that at a specified Ro and δP, similar conversions and yields were achieved using different combinations of time, temperature, and solvent mixture. Using principal component analysis and projection to latent structures, a semi‐empirical model was developed that provided estimates of xylose conversion and furfural yield over a range of experimental Ro and δP values.
Impact of Xylose on Dynamics of Water Diffusion in Mesoporous Zeolites Measured by NMR
(2021-09) Nelson, Madison L.; Romo, Joelle E.; Wettstein, Stephanie G.; Seymour, Joseph D.
Zeolites are known to be effective catalysts in biomass converting processes. Understanding the mesoporous structure and dynamics within it during such reactions is important in effectively utilizing them. Nuclear magnetic resonance (NMR) T2 relaxation and diffusion measurements, using a high-power radio frequency probe, are shown to characterize the dynamics of water in mesoporous commercially made 5A zeolite beads before and after the introduction of xylose. Xylose is the starting point in the dehydration into furfural. The results indicate xylose slightly enhances rotational mobility while it decreases translational motion through altering the permeability, K, throughout the porous structure. The measurements show xylose inhibits pure water from relocating into larger pores within the zeolite beads where it eventually is expelled from the bead itself.