Your search keyword '"Hollow CoP@MoS2 hetero-nanoframe"' showing total 3 results

1. A subtle functional design of hollow CoP@MoS2 hetero-nanoframes with excellent hydrogen evolution performance

Author

Tianyu Xia, Liang Zhou, Shuaiqi Gu, Han Gao, Xiaoyan Ren, Shunfang Li, Rongming Wang, and Haizhong Guo

Subjects

Hollow CoP@MoS2 hetero-nanoframe, Hydrogen evolution, Strong interaction, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

As the star material among nonprecious electrocatalysts, molybdenum disulfide (MoS2) has received much attention. However, the catalytic inertness of the basal plane, low conductivity of its steady state (2H phase), and the agglomeration of lamellar structures have seriously hindered its catalytic performance. It is very essential to design and modulate the morphology and phase of MoS2 to improve the above issues by synergistic regulation of electrical structure and defect engineering. Herein, MoS2 was delicately composited on CoP nanoframe derived from a typical metal–organic frame nanostructure (ZIF-67), forming the hollow CoP@MoS2 hetero-nanoframe. This exquisite externally layered and internally hollow CoP@MoS2 electrocatalyst demonstrated excellent catalytic performance for the hydrogen evolution reaction, with a low overpotential of 119 mV at 10 mA cm−2, a small Tafel slope of 49 mV dec−1, a large electric double-layer capacitance of 10.28 mF cm−2, and prominent long-term stability. The remarkable catalytic performance of hollow CoP@MoS2 hetero-nanoframe can be attributed to the unique architecture of the hetero-nanostructures, appropriate component ratios, strong interaction between CoP and MoS2, and large-scale defects and disorder. First-principles density-functional theory calculations can prove the above arguments adequately, the hydrogen adsorption free energy of CoP@MoS2 is close to zero.

Published

2021

2. A subtle functional design of hollow CoP@MoS2 hetero-nanoframes with excellent hydrogen evolution performance

Author

Xiaoyan Ren, Han Gao, Tianyu Xia, Haizhong Guo, Shuaiqi Gu, Rongming Wang, Liang Zhou, and Shunfang Li

Subjects

Tafel equation, Materials science, Nanostructure, Mechanical Engineering, Strong interaction, Overpotential, Electrocatalyst, Hollow CoP@MoS2 hetero-nanoframe, Catalysis, chemistry.chemical_compound, chemistry, Chemical engineering, Mechanics of Materials, Phase (matter), TA401-492, General Materials Science, Lamellar structure, Hydrogen evolution, Materials of engineering and construction. Mechanics of materials, Molybdenum disulfide

Abstract

As the star material among nonprecious electrocatalysts, molybdenum disulfide (MoS2) has received much attention. However, the catalytic inertness of the basal plane, low conductivity of its steady state (2H phase), and the agglomeration of lamellar structures have seriously hindered its catalytic performance. It is very essential to design and modulate the morphology and phase of MoS2 to improve the above issues by synergistic regulation of electrical structure and defect engineering. Herein, MoS2 was delicately composited on CoP nanoframe derived from a typical metal–organic frame nanostructure (ZIF-67), forming the hollow CoP@MoS2 hetero-nanoframe. This exquisite externally layered and internally hollow CoP@MoS2 electrocatalyst demonstrated excellent catalytic performance for the hydrogen evolution reaction, with a low overpotential of 119 mV at 10 mA cm−2, a small Tafel slope of 49 mV dec−1, a large electric double-layer capacitance of 10.28 mF cm−2, and prominent long-term stability. The remarkable catalytic performance of hollow CoP@MoS2 hetero-nanoframe can be attributed to the unique architecture of the hetero-nanostructures, appropriate component ratios, strong interaction between CoP and MoS2, and large-scale defects and disorder. First-principles density-functional theory calculations can prove the above arguments adequately, the hydrogen adsorption free energy of CoP@MoS2 is close to zero.

Published

2021

3. A subtle functional design of hollow CoP@MoS2 hetero-nanoframes with excellent hydrogen evolution performance.

Author

Xia, Tianyu, Zhou, Liang, Gu, Shuaiqi, Gao, Han, Ren, Xiaoyan, Li, Shunfang, Wang, Rongming, and Guo, Haizhong

Subjects

*OXYGEN evolution reactions, *HYDROGEN evolution reactions, *CHARGE transfer, *ELECTRIC capacity, *HYDROGEN, *MOLYBDENUM disulfide, *OVERPOTENTIAL

Abstract

[Display omitted] • An exquisite externally layered and internally hollow CoP@MoS 2 electrocatalyst was successfully prepared. • CoP can effectively enhance the catalytic ability of MoS 2 on hydrogen evolution reaction. • The externally layered and internally hollow nanostructure can accelerate the transfer of charge and mass. As the star material among nonprecious electrocatalysts, molybdenum disulfide (MoS 2) has received much attention. However, the catalytic inertness of the basal plane, low conductivity of its steady state (2H phase), and the agglomeration of lamellar structures have seriously hindered its catalytic performance. It is very essential to design and modulate the morphology and phase of MoS 2 to improve the above issues by synergistic regulation of electrical structure and defect engineering. Herein, MoS 2 was delicately composited on CoP nanoframe derived from a typical metal–organic frame nanostructure (ZIF-67), forming the hollow CoP@MoS 2 hetero-nanoframe. This exquisite externally layered and internally hollow CoP@MoS 2 electrocatalyst demonstrated excellent catalytic performance for the hydrogen evolution reaction, with a low overpotential of 119 mV at 10 mA cm−2, a small Tafel slope of 49 mV dec−1, a large electric double-layer capacitance of 10.28 mF cm−2, and prominent long-term stability. The remarkable catalytic performance of hollow CoP@MoS 2 hetero-nanoframe can be attributed to the unique architecture of the hetero-nanostructures, appropriate component ratios, strong interaction between CoP and MoS 2 , and large-scale defects and disorder. First-principles density-functional theory calculations can prove the above arguments adequately, the hydrogen adsorption free energy of CoP@MoS 2 is close to zero. [ABSTRACT FROM AUTHOR]

Published

2021