Your search keyword '"Changpeng Liu"' showing total 9 results

1. Monosymmetric Fe-N4 sites enabling durable proton exchange membrane fuel cell cathode by chemical vapor modification

Author

Jingsen Bai, Tuo Zhao, Mingjun Xu, Bingbao Mei, Liting Yang, Zhaoping Shi, Siyuan Zhu, Ying Wang, Zheng Jiang, Jin Zhao, Junjie Ge, Meiling Xiao, Changpeng Liu, and Wei Xing

Subjects

Science

Abstract

Abstract The limited durability of metal-nitrogen-carbon electrocatalysts severely restricts their applicability for the oxygen reduction reaction in proton exchange membrane fuel cells. In this study, we employ the chemical vapor modification method to alter the configuration of active sites from FeN4 to the stable monosymmetric FeN2+N’2, along with enhancing the degree of graphitization in the carbon substrate. This improvement effectively addresses the challenges associated with Fe active center leaching caused by N-group protonation and free radicals attack due to the 2-electron oxygen reduction reaction. The electrocatalyst with neoteric active site exhibited excellent durability. During accelerated aging test, the electrocatalyst exhibited negligible decline in its half-wave potential even after undergoing 200,000 potential cycles. Furthermore, when subjected to operational conditions representative of fuel cell systems, the electrocatalyst displayed remarkable durability, sustaining stable performance for a duration exceeding 248 h. The significant improvement in durability provides highly valuable insights for the practical application of metal-nitrogen-carbon electrocatalysts.

Published

2024

2. Customized reaction route for ruthenium oxide towards stabilized water oxidation in high-performance PEM electrolyzers

Author

Zhaoping Shi, Ji Li, Yibo Wang, Shiwei Liu, Jianbing Zhu, Jiahao Yang, Xian Wang, Jing Ni, Zheng Jiang, Lijuan Zhang, Ying Wang, Changpeng Liu, Wei Xing, and Junjie Ge

Subjects

Science

Abstract

The poor stability of ruthenium-based catalysts has greatly hampered their application in polymer electrolyte membrane water electrolysis. Here, the authors uncover the decisive role of reaction route on catalytic performance, which enables the screening of efficient ruthenium-based water oxidation catalysts.

Published

2023

3. Reactant friendly hydrogen evolution interface based on di-anionic MoS2 surface

Author

Zhaoyan Luo, Hao Zhang, Yuqi Yang, Xian Wang, Yang Li, Zhao Jin, Zheng Jiang, Changpeng Liu, Wei Xing, and Junjie Ge

Subjects

Science

Abstract

H2 energy as an alternative to fossil fuels requires cost-effective catalysts with fast kinetics for splitting water. Here, authors design MoS2 materials with di-anionic surfaces to improve the electrocatalytic H2 evolution activities.

Published

2020

4. Chemically activating MoS2 via spontaneous atomic palladium interfacial doping towards efficient hydrogen evolution

Author

Zhaoyan Luo, Yixin Ouyang, Hao Zhang, Meiling Xiao, Junjie Ge, Zheng Jiang, Jinlan Wang, Daiming Tang, Xinzhong Cao, Changpeng Liu, and Wei Xing

Subjects

Science

Abstract

While water reduction may provide a carbon-neutral means to produce hydrogen gas, there is a scarcity of efficient, earth-abundant electrocatalysts. Here, the authors add palladium into MoS2 materials to activate and stabilize the conductive basal plane to improve the electrocatalytic activity.

Published

2018

5. Reactant friendly hydrogen evolution interface based on di-anionic MoS2 surface

Author

Yang Li, Yuqi Yang, Zhaoyan Luo, Wei Xing, Changpeng Liu, Junjie Ge, Zhao Jin, Xian Wang, Hao Zhang, and Zheng Jiang

Subjects

Materials science, Hydronium, Science, Heteroatom, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, Electrocatalyst, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Catalysis, chemistry.chemical_compound, Molecule, lcsh:Science, Multidisciplinary, Hydrogen bond, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Chemical engineering, chemistry, Hydrogen fuel, Water splitting, lcsh:Q, 0210 nano-technology

Abstract

Engineering the reaction interface to preferentially attract reactants to inner Helmholtz plane is highly desirable for kinetic advancement of most electro-catalysis processes, including hydrogen evolution reaction (HER). This, however, has rarely been achieved due to the inherent complexity for precise surface manipulation down to molecule level. Here, we build a MoS2 di-anionic surface with controlled molecular substitution of S sites by –OH. We confirm the –OH group endows the interface with reactant dragging functionality, through forming strong non-covalent hydrogen bonding to the reactants (hydronium ions or water). The well-conditioned surface, in conjunction with activated sulfur atoms (by heteroatom metal doping) as active sites, giving rise to up-to-date the lowest over potential and highest intrinsic activity among all the MoS2 based catalysts. The di-anion surface created in this study, with atomic mixing of active sites and reactant dragging functionalities, represents a effective di-functional interface for boosted kinetic performance. H2 energy as an alternative to fossil fuels requires cost-effective catalysts with fast kinetics for splitting water. Here, authors design MoS2 materials with di-anionic surfaces to improve the electrocatalytic H2 evolution activities.

Published

2020

6. Chemically activating MoS2 via spontaneous atomic palladium interfacial doping towards efficient hydrogen evolution

Author

Dai-Ming Tang, Jinlan Wang, Zheng Jiang, Junjie Ge, Changpeng Liu, Wei Xing, Hao Zhang, Zhaoyan Luo, Yixin Ouyang, Meiling Xiao, and Xinzhong Cao

Subjects

Materials science, Hydrogen, Science, General Physics and Astronomy, chemistry.chemical_element, Exchange current density, 02 engineering and technology, Overpotential, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Catalysis, chemistry.chemical_compound, lcsh:Science, Molybdenum disulfide, Hydrogen production, Multidisciplinary, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Chemical engineering, lcsh:Q, 0210 nano-technology, Platinum, Palladium

Abstract

Lacking strategies to simultaneously address the intrinsic activity, site density, electrical transport, and stability problems of chalcogels is restricting their application in catalytic hydrogen production. Herein, we resolve these challenges concurrently through chemically activating the molybdenum disulfide (MoS2) surface basal plane by doping with a low content of atomic palladium using a spontaneous interfacial redox technique. Palladium substitution occurs at the molybdenum site, simultaneously introducing sulfur vacancy and converting the 2H into the stabilized 1T structure. Theoretical calculations demonstrate the sulfur atoms next to the palladium sites exhibit low hydrogen adsorption energy at –0.02 eV. The final MoS2 doped with only 1wt% of palladium demonstrates exchange current density of 805 μA cm−2 and 78 mV overpotential at 10 mA cm−2, accompanied by a good stability. The combined advantages of our surface activating technique open the possibility of manipulating the catalytic performance of MoS2 to rival platinum. While water reduction may provide a carbon-neutral means to produce hydrogen gas, there is a scarcity of efficient, earth-abundant electrocatalysts. Here, the authors add palladium into MoS2 materials to activate and stabilize the conductive basal plane to improve the electrocatalytic activity.

Published

2018

7. Reactant friendly hydrogen evolution interface based on di-anionic MoS

Author

Zhaoyan, Luo, Hao, Zhang, Yuqi, Yang, Xian, Wang, Yang, Li, Zhao, Jin, Zheng, Jiang, Changpeng, Liu, Wei, Xing, and Junjie, Ge

Subjects

Hydrogen fuel, Nanoscale materials, Catalyst synthesis, Electrocatalysis, Article

Abstract

Engineering the reaction interface to preferentially attract reactants to inner Helmholtz plane is highly desirable for kinetic advancement of most electro-catalysis processes, including hydrogen evolution reaction (HER). This, however, has rarely been achieved due to the inherent complexity for precise surface manipulation down to molecule level. Here, we build a MoS2 di-anionic surface with controlled molecular substitution of S sites by –OH. We confirm the –OH group endows the interface with reactant dragging functionality, through forming strong non-covalent hydrogen bonding to the reactants (hydronium ions or water). The well-conditioned surface, in conjunction with activated sulfur atoms (by heteroatom metal doping) as active sites, giving rise to up-to-date the lowest over potential and highest intrinsic activity among all the MoS2 based catalysts. The di-anion surface created in this study, with atomic mixing of active sites and reactant dragging functionalities, represents a effective di-functional interface for boosted kinetic performance., H2 energy as an alternative to fossil fuels requires cost-effective catalysts with fast kinetics for splitting water. Here, authors design MoS2 materials with di-anionic surfaces to improve the electrocatalytic H2 evolution activities.

Published

2019

8. Reactant friendly hydrogen evolution interface based on di-anionic MoS2 surface.

Author

Zhaoyan Luo, Hao Zhang, Yuqi Yang, Xian Wang, Yang Li, Zhao Jin, Zheng Jiang, Changpeng Liu, Wei Xing, and Junjie Ge

Subjects

HYDROGEN evolution reactions, BIOCHEMICAL substrates, OXONIUM ions, BASE catalysts, HYDROGEN bonding, HYDROGEN

Abstract

Engineering the reaction interface to preferentially attract reactants to inner Helmholtz plane is highly desirable for kinetic advancement of most electro-catalysis processes, including hydrogen evolution reaction (HER). This, however, has rarely been achieved due to the inherent complexity for precise surface manipulation down to molecule level. Here, we build a MoS2 di-anionic surface with controlled molecular substitution of S sites by -OH. We confirm the -OH group endows the interface with reactant dragging functionality, through forming strong non-covalent hydrogen bonding to the reactants (hydronium ions or water). The wellconditioned surface, in conjunction with activated sulfur atoms (by heteroatom metal doping) as active sites, giving rise to up-to-date the lowest over potential and highest intrinsic activity among all the MoS2 based catalysts. The di-anion surface created in this study, with atomic mixing of active sites and reactant dragging functionalities, represents a effective difunctional interface for boosted kinetic performance. [ABSTRACT FROM AUTHOR]

Published

2020

9. Chemically activating MoS2 via spontaneous atomic palladium interfacial doping towards efficient hydrogen evolution.

Author

Zhaoyan Luo, Yixin Ouyang, Hao Zhang, Meiling Xiao, Junjie Ge, Zheng Jiang, Jinlan Wang, Daiming Tang, Xinzhong Cao, Changpeng Liu, and Wei Xing

Abstract

Lacking strategies to simultaneously address the intrinsic activity, site density, electrical transport, and stability problems of chalcogels is restricting their application in catalytic hydrogen production. Herein, we resolve these challenges concurrently through chemically activating the molybdenum disulfide (MoS2) surface basal plane by doping with a low content of atomic palladium using a spontaneous interfacial redox technique. Palladium substitution occurs at the molybdenum site, simultaneously introducing sulfur vacancy and converting the 2H into the stabilized 1T structure. Theoretical calculations demonstrate the sulfur atoms next to the palladium sites exhibit low hydrogen adsorption energy at –0.02 eV. The final MoS2 doped with only 1wt% of palladium demonstrates exchange current density of 805 μA cm−2 and 78 mV overpotential at 10 mA cm−2, accompanied by a good stability. The combined advantages of our surface activating technique open the possibility of manipulating the catalytic performance of MoS2 to rival platinum. [ABSTRACT FROM AUTHOR]

Published

2018