dc.description.abstract |
Production of fuel range chemicals from biomassderived carbonyls is a viable strategy to overcome the dependency
on nonrenewable fossil fuels. Acid−base catalytic processes play a
vital role in producing liquid fuel range chemicals and
intermediates derived from renewable biomass. Aldol condensation
is one of the simplest ways to convert biomass-derived carbonyls to
C8−C15 range fuels. Herein, CePO4 possessing acidic and basic
sites is synthesized under basic pH and used as catalyst support to
decorate Pd nanoparticles to fabricate a Pd/CePO4 catalyst. Pd/
CePO4 facilitates aldol condensation to form a highly selective α,βunsaturated methyl ketone in the first step, followed by the
selective reduction of CC to form a C−C coupled hydrogenated
product containing a CO functional group in a one-pot cascade
protocol. Many biomass and non-biomass-derived aldehydes are reacted with acetone and methyl isobutyl ketone (MIBK) for the
selective production of fuel precursors. Pyridine Fourier transform infrared (FT-IR) and NH3/CO2 temperature-programmed
desorption (TPD) measurements are employed to probe the acidity and basicity of the catalyst. The influence of different Pd
loadings on the reducibility of these catalysts is studied by H2 temperature-programmed reduction (TPR) analysis. The activation
energy (Ea) for aldol condensation between furfural and acetone is estimated to be 55.3 kJ/mol. The present catalytic system offers a
higher furfural conversion (99.0%) with a higher selectivity (93.6%) of the desired hydrogenated product. Production of furan-based
higher-carbon-containing compounds having carbonyl functionality using a simple and robust metal phosphate-based catalyst would
be highly interesting from industrial and academic perspectives for fuel/chemical production. |
en_US |