Abstract
Hydrothermal deoxygenation of tall oil fatty acids (TOFA) was investigated in the presence of aqueous formic acid (0.5–7.5 wt%) as a H2 donor in the presence of subcritical H2O pressure (569–599 K). Pd and Ru nanoparticles supported on carbon (5% Pd/CSigma, 5% Ru/CSigma, 10% Pd/CO850_DP, and 5% Ru/COPcomm_DP) were found to be efficient catalysts for deoxygenation of TOFA. The reaction pathway was mainly influenced by the concentration of formic acid and the catalyst. In case of Pd catalysts, in the presence of 0–2.5 wt% formic acid, decarboxylation was the dominant pathway producing n-paraffinic hydrocarbons with one less carbon atom (heptadecane yield up to 94 wt%), while with 5–7.5% formic acid, a hydrodeoxygenation/hydrogenation mechanism was favored producing C18 deoxygenation products octadecanol and octadecane as the main products (yields up to 70 wt%). In contrast, Ru catalysts produced a mixture of C5-C20 (n-and iso-paraffinic) hydrocarbons via decarboxylation, cracking and isomerization (up to 58 wt% C17 yield and total hydrocarbon yield up to 95 wt%) irrespective of formic acid concentration. Kinetic studies showed that the rates of deoxygenation displayed Arrhenius type behavior with apparent activation energies of 134.44 ± 31.36 kJ/mol and 148.92 ± 3.66 kJ/mol, for the 5% Pd/CSigma and 5% Ru/CSigma catalyst, respectively. Furthermore, the experiments with glycerol tristearate, rapeseed oil, sunflower oil, rapeseed biodiesel, and hydrolyzed rapeseed oil produced identical products confirming the versatility of the aforementioned catalytic systems for deoxygenation of C18 feedstocks.
Highlights
IntroductionIts use has several drawbacks, especially with regard to fuel quality (viscosity, low energy density, strong solvent properties, etc.) and storage stability (oxidative fouling, algae growth)
Keeping the above points in mind, the present study was undertaken with the aim of investigating hydrothermal decarboxylation/deoxygenation of tall oil fatty acids (TOFA) and related fatty acid derivatives in the presence of aqueous formic acid with carbon supported Pd and Ru catalysts
To further evaluate the activity and selectivity of Pd- and Rubased catalysts, we evaluated the effect of batch holding time upon TOFA deoxygenation with 2.5 wt% aqueous formic acid at 599 K using two representative catalysts 5% Pd/CSigma and 5% Ru/CSigma, respectively
Summary
Its use has several drawbacks, especially with regard to fuel quality (viscosity, low energy density, strong solvent properties, etc.) and storage stability (oxidative fouling, algae growth) Due to these shortcomings, the use of biodiesel in existing diesel engines has often been limited to low volumetric percentage (5–7%) with petroleum diesel [6]. As a matter of fact, due to the low hydrogen requirement and favorable dehydrogenation conditions (aqueous phase reforming), hydrothermal decarboxylation has been demonstrated to be efficient with in situ generated hydrogen (catalytic transfer hydrogenation) for production of diesel-like hydrocarbons from fats and oils [26,27,28]. Supercritical water has been reported to catalyze the decomposition of formic acid to H2 and CO2 The latter, in particular, has potential for application in aqueous phase processing of oxygenated biomolecules into high-value products like synthetic hydrocarbons. Keeping the above points in mind, the present study was undertaken with the aim of investigating hydrothermal decarboxylation/deoxygenation of TOFA and related fatty acid derivatives in the presence of aqueous formic acid with carbon supported Pd and Ru catalysts
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