Catalytic Conversion of Lignin and Lignin-Derived β-O-4 Ether to Cyclohexanols over a CeO<sub>2</sub>-Doped Carbon-Supported Nickel-Based Catalyst
Jin-Xuan Xie, Yun‐Peng Zhao, Qiang Li, Le‐Le Qiu, Fang‐Jing Liu, Jing Liang, Jian Li, Jing‐Pei Cao
Abstract
In this study, a CeO 2 -doped carbon-supported nickel-based catalyst (Ni/XCeO 2 –C–Y) was synthesized and applied to the catalytic depolymerization of lignin and its derivatives. The variations in CeO 2 content and calcination temperature are observed to cause a notable impact on the existence of oxygen vacancies. The results demonstrated that an optimal Ni/20%CeO 2 –C-500 exhibited excellent effectiveness in the cleavage of the β-O-4 bond to ethylbenzene and cyclohexanol at 180 °C and 1 MPa N 2 . In this system, isopropanol is used as a hydrogen-donating solvent as it can produce H 2 (detected by GC) during the reaction. The successful doping of CeO 2 onto carbon contributes to the formation of an interaction between the carrier and nickel, causing a more uniform dispersion of metallic Ni. In addition, the selectivity of phenols in the real lignin depolymerization decreased from noncatalytic 71.5 to 25.4%, and most of the phenols were well converted into cyclohexanols and ketones. The reusability experiments revealed that Ni/20%CeO 2 –C-500 possessed excellent recycling and regeneration properties.