Slurry-Phase Hydrocracking of Heavy Oil with Bifunctional Catalysts In Situ Generated from Oil-Soluble Ionic Liquid and Mixed Metal Oxide

Abstract: In this work, an oil-soluble ionic liquid (IL) was combined with mixed metal oxide for in situ generation of bifunctional catalysts for slurry-phase heavy oil hydrocracking. The oil-soluble IL selected was trihexylmethylammonium molybdate ([N6661]2MoO4), and the mixed metal oxide selected was SiO2–ZrO2. The performance of using [N6661]2MoO4 and SiO2–ZrO2 for slurry-phase hydrocracking was examined systematically. It is found that the addition of SiO2–ZrO2 can significantly improve the conversion of residue to … Show more

“…Ma et al 11 demonstrate the efficacy of combining an oilsoluble ionic liquid with mixed-metal oxides for in situ generation of bifunctional catalysts in slurry-phase heavy-oil hydrocracking. The addition of SiO 2 −ZrO 2 significantly enhances residue conversion to distillate, with improved gas and coke yields.…”

Honoring Prof. Muthanna H. Al-Dahhan

“…Ma et al 11 demonstrate the efficacy of combining an oilsoluble ionic liquid with mixed-metal oxides for in situ generation of bifunctional catalysts in slurry-phase heavy-oil hydrocracking. The addition of SiO 2 −ZrO 2 significantly enhances residue conversion to distillate, with improved gas and coke yields.…”

Honoring Prof. Muthanna H. Al-Dahhan

Silica Janus nanosheets anchored with Ni nanoparticles for in-situ upgrading and stimulus-responsive demulsification to enhance heavy oil recovery

Synthesis, self-aggregation, thermal stability and cytotoxicity trends of alkyloxypropoxycyclohexane based pyridinium ionic liquids