Your search keyword '"Dong, Lichun"' showing total 3 results

1. Silica-coated LaNiO3 nanoparticles for non-thermal plasma assisted dry reforming of methane: Experimental and kinetic studies.

Author

Zheng, Xiaogang, Tan, Shiyu, Dong, Lichun, Li, Shaobo, and Chen, Hongmei

Subjects

*SILICA nanoparticles, *NON-thermal plasmas, *LANTHANUM compounds, *SURFACE coatings, *METHANE, *CHEMICAL kinetics

Abstract

Silica-coated LaNiO 3 nanoparticles (LaNiO 3 @SiO 2 NPs) were prepared by the modified Stöber method for the conversion of methane with carbon dioxide into syngas in a dielectric barrier discharge reactor (DBD) under ambient conditions. The synergistic effect of LaNiO 3 @SiO 2 NPs and DBD plasma toward the dry reforming of methane was investigated as a function of flow rate of feed gases, input power, and molar ratio of CH 4 /CO 2 . The results indicated that the Ni–La 2 O 3 @SiO 2 produced from LaNiO 3 @SiO 2 NPs showed high catalytic activity for the plasma-assisted dry reforming of methane due to the creation of a silica shell. The Koros–Nowak criterion test demonstrated that the catalytic activity of Ni–La 2 O 3 @SiO 2 sample was independent of the transport phenomenon. A semi-empirical power-law rate equation was applied to investigate the kinetic behavior of Ni–La 2 O 3 @SiO 2 catalyst for the plasma-assisted dry reforming of CH 4 and evaluate its kinetic parameters, including activation energy, rate constant, and reaction orders. Compared to the activation energy estimated for CO 2 consumption, lower value of CH 4 conversion corresponded to its higher reaction rate. [ABSTRACT FROM AUTHOR]

Published

2015

2. Selective hydrogenation of acetylene on carbon-encapsulated Ni-Co-Cu trimetallic nanoparticles: Synergizing electronic effects and spatial confinement.

Author

Zhou, Shihong, Lu, Chenyang, Bi, Yi, Zhou, Cailong, Li, Qun, Tan, Luxi, and Dong, Lichun

Subjects

*POLAR effects (Chemistry), *ACETYLENE, *ALUMINUM oxide, *WATER gas shift reactions, *HYDROGENATION, *COPPER

Abstract

[Display omitted] • The Al 2 O 3 supported carbon coated NiCuCo alloy were prepared via a simple method. • The trade-off between activity and selectivity was overcome on NiCuCo@C/Al 2 O 3. • The electron-rich Ni species weaken the desorption of acetylene and ethylene. • The reduced formation of green oil results in excellent stability. Achieving high ethylene selectivity and activity simultaneously for acetylene selective hydrogenation still remains challenging. Here, the challenge of the trade-off between activity and selectivity was solved by synergizing electronic effects and spatial confinement, which was achieved by confining the Ni-Co-Cu trimetallic nanoparticles in a carbon layer (Ni x Cu y Co z @C/Al 2 O 3). Compared to the catalyst without carbon encapsulation (Ni x Cu y Co z /Al 2 O 3), Ni x Cu y Co z @C/Al 2 O 3 showed superior catalytic performance in terms of enhanced activity, selectivity and stability. Under optimal conditions, acetylene conversion of 100% and ethylene selectivity of 89% were achieved, whereas Ni x Cu y Co z /Al 2 O 3 exhibited lower acetylene conversion (92%) and ethylene selectivity (21%). Detailed characterizations reveal that the electronic structure can be regulated flexibly by controlling the composition of Ni-Co-Cu nanoparticles. The enhanced activity and selectivity were attributed to the weakened adsorption of acetylene and ethylene on the electron-rich Ni. The improved stability was related to the carbon layer, which suppressed the acetylene coupling by the acidic sites on the Al 2 O 3 surface. [ABSTRACT FROM AUTHOR]

Published

2023

3. Carbon-confined Cu-Pd alloy nanoparticles as high-performance catalysts for acetylene selective hydrogenation.

Author

Lu, Chenyang, Zhou, Shihong, Zhou, Wenyu, Zhou, Cailong, Li, Qun, Zeng, Aonan, Wang, Anjie, Tan, Luxi, and Dong, Lichun

Subjects

*ACETYLENE, *CATALYST selectivity, *HYDROGENATION, *CATALYSTS, *COPPER, *VINYL acetate

Abstract

[Display omitted] • Carbon confined Cu-Pd nanoalloy catalysts are successfully synthesized through an eco-friendly, facile and efficient approach. • Carbon encapsulation strategy efficiently improves the ethylene selectivity and stability for selective hydrogenation of acetylene. • Carbon layer acts as "cages" for confining the growth of the carbon chain to oligomer during the acetylene hydrogenation. • This synthesis strategy can be extended to other carbon confined Cu and Ag-based bimetal catalysts. A catalyst with high selectivity for acetylene selective hydrogenation is highly desirable, yet ideal selectivity often comes at the price of activity loss. Here, a carbon confined Cu 15 Pd catalyst (Cu 15 Pd@C) was fabricated through an eco-friendly and efficient approach, which improves ethylene selectivity while at the same time, maintains high activity. Under optimized conditions, acetylene conversion of 100% and ethylene selectivity of 91% were simultaneously achieved. Comprehensive characterization and DFT reveal that the carbon layer not only promotes the formation of smaller nanoparticles, but effectively inhibits the production of green oil, which is associated to the confined spatial microenvironment by the carbon layer, posing steric hindrance to chain growth from acetylene coupling. A series of carbon confined Cu and Ag-based bimetal catalysts were fabricated through the same method, proving the facilitation of carbon layer on such selective hydrogenation universal, and also showed great potential of our method and catalysts in practical application. [ABSTRACT FROM AUTHOR]

Published

2023