The surface structures of ReO x supported on CeO 2 at low loadings have been elucidated through 18 O isotopic exchange Raman spectroscopy and diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS). The ReO x is present in four distinct structures, a di-oxo structure with two ReO terminal bonds, a mono-oxo species that contains one ReO terminal bond, a mono-oxo species that contains a hydroxyl group, and a crosslinked ReO x species. The isotopic exchange Raman spectroscopy shows a red shift resulting from the 18 O exchange in the OReO, ReO, Re−OH, and Re−O−Re species, which allowed for the deconvolution of the various structures. Time-resolved DRIFTS showed significant exchange of 18 O over time and reconfirmed the results from the Raman spectroscopy. The presence of multiple surface species supports the existence of competing reaction mechanisms for the simultaneous hydrodeoxygenation over the ReO x −Pd/ CeO 2 catalyst and deoxydehydration over the ReO x /CeO 2 catalyst.
In
this study, we demonstrate that for the simultaneous hydrodeoxygenation
(HDO) of 1,4-anhydroerythritol a comparable yield of tetrahydrofuran
is obtained at half the previously reported H2 pressure.
The simultaneous hydrodeoxygenation was conducted using a heterogeneous
ReO
x
–Pd/CeO2 catalyst.
An L9 Taguchi design of experiment was enacted to elucidate the temperature,
pressure, and catalyst loading effects on the yield of the HDO reaction
by testing pressures ranging from 40 to 80 bar H2, temperatures
of 100–180 °C, and Re loadings of 2–4 wt %. Our
design showed that the yield of this reaction is significantly affected
by the reaction temperature only. An L9 Taguchi design was conducted
for xylitol simultaneous hydrodeoxygenation with pressures ranging
from 5 to 10 bar H2, temperatures of 140–180 °C,
and Re loadings of 2–4 wt %. The xylitol design elucidated
the direct relation of pressure, and the inverse relation of temperature
and catalyst loading, to yield with the optimal reaction condition
being 140 °C and 10 bar H2.
Selective
removal of oxygen from biomass-derived polyols is critical
toward bridging the gap between biomass feedstocks and the production
of commodity chemicals. In this work, we show that earth-abundant
molybdenum oxide based heterogeneous catalysts are active, selective,
and stable for the cleavage of vicinal C–O bonds in biomass-derived
polyols. Catalyst characterization (Raman spectroscopy, X-ray photoelectron
spectroscopy (XPS), diffuse reflectance infrared Fourier transform
spectroscopy (DRIFTS)) shows that partially reduced MoO
x
centers are responsible for C–O bond cleavage
and are generated in situ by hydrogen dissociated
atoms over palladium (Pd) nanoparticles. We find that the support,
TiO2, facilitates communication between the hydrogen dissociating
metal and dispersed MoO
x
sites through
hydrogen spillover. Reactivity studies using a biomass-derived model
substrate (1,4-anhydroerythritol) show the effective removal of vicinal
hydroxyls over MoO
x
-Pd/TiO2 producing tetrahydrofuran with >98% selectivity at 29% conversion.
Catalyst stability is demonstrated upon cycling. These studies are
critical toward the development of low-cost heterogeneous catalysts
for sustainable hydrodeoxygenation of biobased polyols to platform
chemicals.
Thermochemical conversion of tobacco residues to value-added bio-fuels and chemicals via fast pyrolysis, in combination with torrefaction pretreatment, in a rotating blade ablative reactor under vacuum conditions.
In this study, we elucidate the reaction kinetics for the simultaneous hydrodeoxygenation of xylitol to 1,2-dideoxypentitol and 1,2,5-pentanetriol over a ReOx-Pd/CeO2 (2.0 weight% Re, 0.30 weight% Pd) catalyst. The reaction was determined to be a zero-order reaction with respect to xylitol. The activation energy was elucidated through an Arrhenius relationship as well as non-Arrhenius kinetics. The Arrhenius relationship was investigated at 150–170 °C and a constant H2 pressure of 10 bar resulting in an activation energy of 48.7 ± 10.5 kJ/mol. The investigation of non-Arrhenius kinetics was conducted at 120–170 °C and a sub-Arrhenius relation was elucidated with activation energy being dependent on temperature, and ranging from 10.2–51.8 kJ/mol in the temperature range investigated. Internal and external mass transfer were investigated through evaluating the Weisz–Prater criterion and the effect of varying stirring rate on the reaction rate, respectively. There were no internal or external mass transfer limitations present in the reaction.
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