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294 results on '"Qin, Jun‐Sheng"'

13. Molecular Engineering of Porous Fe‐N‐C Catalyst with Sulfur Incorporation for Boosting CO2 Reduction and Zn‐CO2 Battery.

Author

Han, Jingwei, Xu, Qiang, Rong, Jiaxin, Zhao, Xue, She, Ping, Qin, Jun‐Sheng, and Rao, Heng

Subjects
STANDARD hydrogen electrode, DENSITY functional theory, ELECTROLYTIC reduction, BIOCHEMICAL substrates, ENERGY storage
Abstract

Transition metal‐nitrogen‐carbon (M‐N‐C) catalysts have emerged as promising candidates for electrocatalytic CO2 reduction reaction (CO2RR) due to their uniform active sites and high atomic utilization rate. However, poor efficiency at low overpotentials and unclear reaction mechanisms limit the application of M‐N‐C catalysts. In this study, Fe‐N‐C catalysts are developed by incorporating S atoms onto ordered hierarchical porous carbon substrates with a molecular iron thiophenoporphyrin. The well‐prepared FeSNC catalyst exhibits superior CO2RR activity and stability, attributes to an optimized electronic environment, and enhances the adsorption of reaction intermediates. It displays the highest CO selectivity of 94.0% at −0.58 V (versus the reversible hydrogen electrode (RHE)) and achieves the highest partial current density of 13.64 mA cm−2 at −0.88 V. Furthermore, when employed as the cathode in a Zn‐CO2 battery, FeSNC achieves a high‐power density of 1.19 mW cm−2 and stable charge–discharge cycles. Density functional theory calculations demonstrate that the incorporation of S atoms into the hierarchical porous carbon substrate led to the iron center becoming more electron‐rich, consequently improving the adsorption of the crucial reaction intermediate *COOH. This study underscores the significance of hierarchical porous structures and heteroatom doping for advancing electrocatalytic CO2RR and energy storage technologies. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Dynamic Bond-Directed Synthesis of Stable Mesoporous Metal–Organic Frameworks under Room Temperature

Author

Li, Youcong, primary, Su, Jian, additional, Zhao, Yue, additional, Feng, Liang, additional, Gao, Lei, additional, Xu, Xinyu, additional, Yin, Ya, additional, Liu, Yifan, additional, Xiao, Pengwei, additional, Yuan, Ling, additional, Qin, Jun-Sheng, additional, Wang, Yuanyuan, additional, Yuan, Shuai, additional, Zheng, He, additional, and Zuo, Jing-Lin, additional

Published
2023
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26. Monitoring the Activation of Open Metal Sites in [FexM3–x(μ3-O)] Cluster-Based Metal–Organic Frameworks by Single-Crystal X-ray Diffraction

Author

Chen, Wenmiao, primary, Wang, Zhi, additional, Wang, Qi, additional, El-Yanboui, Khaoula, additional, Tan, Kui, additional, Barkholtz, Heather M., additional, Liu, Di-Jia, additional, Cai, Peiyu, additional, Feng, Liang, additional, Li, Youcong, additional, Qin, Jun-Sheng, additional, Yuan, Shuai, additional, Sun, Di, additional, and Zhou, Hong-Cai, additional

Published
2023
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28. Electrocatalytic reduction of CO2to CO by Fe(iii) carbazole–porphyrins in homogeneous molecular systemsElectronic supplementary information (ESI) available: Experimental procedure, including synthesis and NMR data of iron porphyrins. See DOI: https://doi.org/10.1039/d3cy01618h

Author

Sun, Hai, Wu, Jiahui, Tian, Fengkun, Zhang, Guodong, Xia, Zixiang, Rong, Jiaxin, Qin, Jun-Sheng, and Rao, Heng

Abstract

Iron porphyrins have demonstrated remarkable catalytic activity as electrocatalysts for the carbon dioxide reduction reactions (CO2RR). To enhance their catalytic activity, iron(iii) tetrakis(4-(diphenylamino)phenyl)porphyrin (FeTDPP) and iron(iii) tetrakis(carbazol-9-ylphenyl)porphyrin (FeTCPP) were synthesized by incorporating triphenylamine and phenylcarbazole substituents at the mesoposition. Both FeTDPP and FeTCPP were able to electrocatalytic reduce CO2to CO with a Faraday efficiency exceeding 90%. Compared with the benchmark catalyst, iron(iii) tetra(meso-phenyl)porphyrin (FeTPP), FeTDPP and FeTCPP exhibit lower overpotentials that are positively shifted by approximately 10 mV and 90 mV, respectively.

Published
2024
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29. Photocatalytic nitrogen fixation over flower-like molecular cobalt phthalocyanine@ZnIn2S4 heterojunctions under visible-light irradiation.

Author

She, Ping, Wang, Xiuyan, Bao, Tengfei, Rui, Hongbang, Qi, Yuanyuan, Rao, Heng, Sun, Hang, and Qin, Jun-Sheng

Subjects
NITROGEN fixation, HETEROJUNCTIONS, COBALT, PHOTOREDUCTION, CATALYSTS recycling, IRRADIATION
Abstract

Molecular catalysts (such as metal phthalocyanine (Pc) molecules) have been widely utilized in homogeneous catalytic systems. However, its practical application is still hindered by the weak stability and difficulty to recycle molecular catalysts from the homogeneous solution. An attractive strategy was adopted by combining the molecular Pc catalysts with an inorganic semiconductor, which can solve the recycling issue and improve the photo-induced charge separation simultaneously. Herein, we integrated a molecular Pc catalyst and a spiky-like ZnIn2S4 to conduct the photocatalytic nitrogen reduction reaction (PNRR). The spiky-like composites of ZnIn2S4@Pc demonstrated superior PNRR activity without any sacrificial hole capture (156.59 µmol g−1 h−1), which is contributed by the enhanced light harvesting and charge separation induced by the dimension-matched combination. [ABSTRACT FROM AUTHOR]

Published
2023
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48. Continuous Variation of Lattice Dimensions and Pore Sizes in Metal-Organic Frameworks

Author

Yuan, Shuai, Huang, Lan, Huang, Zhehao, Sun, Di, Qin, Jun-Sheng, Feng, Liang, Li, Jialuo, Zou, Xiaodong, Cagin, Tahir, Zhou, Hong-Cai, Yuan, Shuai, Huang, Lan, Huang, Zhehao, Sun, Di, Qin, Jun-Sheng, Feng, Liang, Li, Jialuo, Zou, Xiaodong, Cagin, Tahir, and Zhou, Hong-Cai

Abstract

The continuous variation of the lattice metric in metal-organic frameworks (MOFs) allows precise control over their chemical and physical properties. This has been realized herein by a series of mixed-linker and Zr-6-cluster-based MOFs, namely, continuously variable MOFs (CVMOFs). Similar to the substitutional solid solutions, organic linkers with different lengths and various ratios were homogeneously incorporated into a framework rather than being allowed to form separate phases or domains, which was manifested by single-crystal X-ray diffraction, powder X-ray diffraction, fluorescence quenching experiments, and molecular simulations. The unit cell dimension, surface area, and pore size of CVMOFs were precisely controlled by adopting different linker sets and linker ratios. We demonstrate that CVMOFs allow the continuous and fine tailoring of cell-edge lengths from 17.83 to 32.63 angstrom, Brunauer-Emmett-Teller (BET) surface areas from 585 to 3791 m(2)g(-1), and pore sizes up to 15.9 angstrom. Furthermore, this synthetic strategy can be applied to other MOF systems with various metal nodes thus allowing for a variety of CVMOFs with unprecedented tunability.

Published
2020
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