Your search keyword '"Yan, Hao"' showing total 2 results

1. Enhanced activity and stability for combined steam and CO2 reforming of methane over NiLa/MgAl2O4 catalyst.

Author

Li, Ze, Leng, Jun, Yan, Hao, Zhang, Dongpei, Ren, Delun, Li, Feilong, Liu, Yibin, Chen, Xiaobo, and Yang, Chaohe

Subjects

*STEAM reforming, *CATALYSTS, *CATALYTIC activity, *CARBON dioxide

Abstract

Ni 10 La x /MAO catalysts with high Ni dispersion was prepared by wet impregnation method. Characterization results showed that metal dispersion of Ni obviously improved on catalyst surface after La doping. Under the long-term reaction conditions (800 °C, 10 h), Ni 10 La 5 /MAO catalyst could exhibit the highest catalytic performance (93% of CH 4 conversion, 71% of CO 2 conversion and less than 3% activity loss) with lower Ni particle size (12.6 nm) and carbon deposition (8.9 %). [Display omitted] • La doping significantly increased the content of active species Ni0. • High dispersion of Ni species efficiently inhibited the growth of carbon. • Ni 10 La 5 /MgAl 2 O 4 catalyst owned the highest catalytic activity and stability in methane bi-reforming system. Ni-based catalysts were widely studied for methane reforming system in the past decades, while catalytic deactivation by carbon deposition and metal sintering limited its industrial application life. In this work, La-promoted Ni/MgAl 2 O 4 catalysts were investigated over methane bi-reforming reaction, and significantly improved the activity and stability of catalysts. Multiple characterizations showed that the introduction of La increased the content and dispersion of active species (Ni0), providing sufficient sites for methane adsorption and dissociation. Besides, smaller particle size of active metal (12.6 nm) was proved to inhibiting carbon accumulation on catalyst surface. Ni 10 La 5 /MgAl 2 O 4 catalyst was found to exhibit the highest catalytic performance (93% of CH 4 conversion, 71% of CO 2 conversion and less than 3% activity loss) under long-term reaction conditions (800 °C, 10 h). This work will provide important guiding significance for the design of high-efficiency methane reforming catalysts. [ABSTRACT FROM AUTHOR]

Published

2023

2. Promoted polysulfide conversion process and improved rate performance by tin atom modified carbon in Li-S batteries.

Author

Wang, Caiwei, Xiao, Qucheng, Yang, Xiayu, Yan, Hao, Qi, Jie, Liu, Shike, Wang, Junmei, and Huang, Jianfeng

Subjects

*LITHIUM sulfur batteries, *CATALYSTS, *HYDROTHERMAL carbonization, *METAL catalysts, *ATOMS, *METAL sulfides, *TIN

Abstract

[Display omitted] • C/Sn 2 S 3 /S is obtained by loading sulfur on the surface of C/Sn. • C/Sn 2 S 3 /S composite electrodes possess good rate performance in Li-S batteries. • Sn atom modified carbon can achieve stable polysulfide conversion process. Dissolution of polysulfides limits the improvement of rate performance in Li-S batteries. Introducing catalytic agents is the key to promote polysulfide conversion process and improve rate performance of Li-S batteries. Both metallic atoms catalysts and metal sulfide catalysts can promote polysulfide conversion process. However, the comparison of catalyzing abilities between metallic atoms catalysts and metal sulfide catalysts in Li-S batteries still needs to be studied. SnS modified carbon (C/SnS) and Sn atom modified carbon (C/Sn) are obtained by controlling hydrothermal and carbonization processes in this paper. Electrochemical performance of C/SnS/S and C/Sn 2 S 3 /S composite electrodes are also studied, which are obtained by loading sulfur on C/SnS and C/Sn. Results show that C/Sn 2 S 3 /S composite electrodes possess higher rate performance (553 mAh·g−1 at 5C) than C/SnS/S composite electrodes, which is ascribe to stable catalyzing abilities of Sn atom modified carbon. Electron transportation abilities and Li-ion diffusion process are both promoted in C/Sn 2 S 3 /S composite electrodes. The comparison of catalyzing abilities between C/SnS and C/Sn composites provides reference for design and regulation of composite structures. [ABSTRACT FROM AUTHOR]

Published

2024