(79f) Reaction of Methyloctanoate over Supported Pt-Pd Catalysts

The use of renewable vegetable oils to produce biodiesel has drawn considerable public attention. However, as-produced biodiesel has some drawbacks such as low stability and fungibility with regular diesel. An interesting additional process to biodiesel production is conversion to alkanes, which can be used as normal diesel. Triglyceride molecules in vegetable oils contain fragments of C14 to C20 straight chains, which can be converted to long paraffins that bear a potentially high cetane number (CN), but at the same time they may result in increased cloud point (CP). In order to be used in regular diesel, these molecules have to undergo mild isomerization to produced mono-branched isoparaffins with still acceptable CN and lower CP. In this work, methyloctanoate (MeOct) has been used as a model compound to study the conversion of biodiesel-like oxygenates to paraffins and isoparaffins, which meet the above requirements. To achieve this goal we have investigated two consecutive catalytic steps: first, deoxygenation of oxygenates to paraffinic compounds and second, mild isomerization of straight-chain products to slightly branched isoparaffins. The reaction studies were carried out over various noble-metal catalysts (Pt-Pd) under three different conditions: a) in pure H2, b) in pure He and c) in 5% H2/He. In all cases, the operating pressure and temperature were kept at 500 psig and 300oC, respectively. We have found that the deoxygenation of MeOct readily occurs over bimetallic 0.4%Pt-0.6%Pd/?×-Al2O3 as well as monometallic 5%Pd/C catalysts in the flow of either H2 or He (see Scheme 1). Interestingly, it was observed that the Pd/C catalyst deactivates much faster than the bimetallic Pt-Pd/?×-Al2O3 under both carrier gases. Under He, the main products from the two catalysts were n-heptane (n-C7) and n-heptenes, which result from decarboxylation and decarbonylation/dehydration of MeOct, respectively. Due to rapid hydrogenation, under H2 flow, the main product was n-C7. Interestingly, the selectivity to n-C8 (a product of C-O bond hydrogenolysis) greatly increased when acidic supports such as W-ZrO2, 3%F-Al2O3 and HY (Si/Al=15) were used. The product ratio n-C8/n-C7 (which can be taken as the ratio of hydrogenolysis-to-decarboxylation) increased for the different supports in the following order: F-Al2O3 HY, which indicates that the isomerization may depend more strongly on the acid strength than density.