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Highly Cr-Substituted CeO<sub>2</sub>Nanoparticles Synthesized Using a Non-equilibrium Supercritical Hydrothermal Process: High Oxygen Storage Capacity Materials Designed for a Low-Temperature Bitumen Upgrading Process

Yuanzheng Zhu, Gimyeong Seong, Takio Noguchi, Akira Yoko, Takaaki Tomai, Seiichi Takami, Tadafumi Adschiri

2020ACS Applied Energy Materials35 citationsDOI

Abstract

As described herein, the synthesis of highly Cr-substituted CeO2 nanoparticles (Cr-CeO2) for low-temperature bitumen upgrading is demonstrated using a supercritical hydrothermal method including a subcritical region. A continuous flow reactor that can provide a non-equilibrium process was used to improve Cr substitution in the CeO2 lattice. Consequently, a Cr-substitution concentration of 22.7 mol %, which was unobtainable using the equilibrium process (5.1 mol %), was achieved. As the Cr-substitution concentration increased, the Cr-CeO2 morphology changed from a perfect octahedron to a cluster of small nanoparticles with high lattice strain. The increase in lattice strain strongly affects the rise in the oxygen storage capacity (OSC) of Cr-CeO2. Results show that high conversion of asphaltene (up to 47.9% at 350 °C) and high selectivity of syngas (H2 and CO, up to 58.3% at 350 °C) were achieved through low-temperature catalytic bitumen upgrading in the presence of highly Cr-substituted CeO2 nanoparticles. Furthermore, results show that the asphaltene conversion increased because of the rise in the OSC of Cr-CeO2, irrespective of the increase in the specific surface area, which indicates that the catalytic potential of Cr-CeO2 is more dependent on OSC than their specific surface area.

Topics & Concepts

Supercritical fluidChemical engineeringHydrothermal circulationMaterials scienceNanoparticleAsphalteneCatalysisNanotechnologyChemistryOrganic chemistryEngineeringSubcritical and Supercritical Water ProcessesCatalytic Processes in Materials SciencePetroleum Processing and Analysis