Conductive CuCo‐Based Bimetal Organic Framework for Efficient Hydrogen Evolution

Geng, Bo; Yan, Feng; Zhang, Xiao; He, Yuxin; Zhu, Chunling; Chou, Shulei; Zhang, Xiaoli; Chen, Yujin

doi:10.1002/adma.202106781

Cited by 132 publications

(87 citation statements)

References 41 publications

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“…2k) show bright ring patterns matching (111), (220), (311), and (222), consistent with the XRD analysis. 31–33 The mapping plot of Fe–Ni–Co (Fig. 2l) illustrates the uniform distribution of Ni, Co, and Fe elements in the samples, consistent with the EDX analysis (Fig.…”

Section: Resultssupporting

confidence: 77%

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Zheng

Sun

et al. 2022

New J. Chem.

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Section: Resultssupporting

confidence: 77%

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Zheng

Sun

et al. 2022

New J. Chem.

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“…In this G-Cu/0.5-Ni-NiO x catalyst structure, G ensured good dispersibility of catalyst NPs. The Cu component constituted the real catalytically active site . The Ni-NiO x component grown on the surface of Cu NPs acted as a protective layer and coordination site, , which can simultaneously enhance the antioxidant performance of copper NPs and ensure the effective adsorption of AB molecules and the generation of H 2 .…”

Section: Results and Discussionmentioning

confidence: 99%

Cu/Ni-NiO_x Nanoparticles Distributed on Graphene as Catalysts for the Methanolysis of Ammonia Borane to Produce Hydrogen

Zheng

Bao

Liu

et al. 2021

ACS Appl. Nano Mater.

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Ultrasmall Cu/Ni-NiO x nanoparticles (NPs) had been successfully prepared by attaching and growing Ni-NiO x NPs on the surface of Cu NPs and then uniformly dispersed onto graphene (G) surface. High-angle annular dark-field–scanning transmission electron microscopy (HAADF-STEM) characterization confirmed that Ni-NiO x NPs were uniformly distributed on the surface of Cu NPs. The catalytic methanolysis of ammonia borane (AB) proved that Cu/Ni-NiO x NPs possessed high catalytic hydrogen (H2) evolution activity, and the highest turnover frequency (TOF) was 17.72 mol H2·mol–1 Cu·min–1. Comparative experiments revealed that the high catalytic activity originated from the abundant catalytic active sites of Cu/Ni-NiO x NPs. The attachment of Ni-NiO x on the surface of Cu NPs that dispersed on G (G-Cu/Ni-NiO x ) can not only effectively improve the antioxidative performance of Cu NPs under ambient conditions but also promote the methanolysis of AB to produce H2.

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“…The transition metal Cu has also achieved a wide range of applications in the field of electrocatalysis, such as HER, CO 2 RR, and LiS battery. [115][116][117] Based on this, Cu SA with two N atoms and two O atomic coordination were employed to sulfur host materials (Cu SA/NOC/S), which expressed a high S loading (67 wt%). [113] These Cu SA were uniformly dispersed on the carbon substrate, as shown in the HAADF-STEM image (Figure 7i).…”

Section: Atomic-scale Catalystsmentioning

confidence: 99%

Electrocatalysis in Room Temperature Sodium‐Sulfur Batteries: Tunable Pathway of Sulfur Speciation

Wang

Zhang

et al. 2022

Small Methods

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Benefiting from the merits of natural abundance, low cost, and ultrahigh theoretical energy density, the room temperature sodium‐sulfur (RT NaS) batteries are regarded as one of the promising candidates for the next‐generation scalable energy storage devices. However, the uncontrollable sulfur speciation pathways severely hinder its practical applications. Recently, various strategies have been employed to tune the conversion pathways of sulfur, such as physical confinement, chemical inhibition, and electrocatalysis. Herein, the recent advances in electrocatalytic effects manipulate sulfur speciation pathways in advanced RT NaS electrochemistry are reviewed, including the promotion of the nearly full conversion of long‐chain polysulfides, short‐chain polysulfides, and small sulfur molecules. The underlying catalytic modulation mechanism that fundamentally tunes the electrochemical pathway of sulfur species is comprehensively summarized along with the design strategies for catalytic active centers. Furthermore, the challenge and potential solutions to realize the quasi‐solid conversion of sulfur are proposed to accelerate the real application of RT NaS batteries.

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Conductive CuCo‐Based Bimetal Organic Framework for Efficient Hydrogen Evolution

Cited by 132 publications

References 41 publications

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Cu/Ni-NiO_x Nanoparticles Distributed on Graphene as Catalysts for the Methanolysis of Ammonia Borane to Produce Hydrogen

Electrocatalysis in Room Temperature Sodium‐Sulfur Batteries: Tunable Pathway of Sulfur Speciation

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Conductive CuCo‐Based Bimetal Organic Framework for Efficient Hydrogen Evolution

Cited by 132 publications

References 41 publications

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Fe–Ni–Co trimetallic oxide hierarchical nanospheres as high-performance bifunctional electrocatalysts for water electrolysis

Cu/Ni-NiOx Nanoparticles Distributed on Graphene as Catalysts for the Methanolysis of Ammonia Borane to Produce Hydrogen

Electrocatalysis in Room Temperature Sodium‐Sulfur Batteries: Tunable Pathway of Sulfur Speciation

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Cu/Ni-NiO_x Nanoparticles Distributed on Graphene as Catalysts for the Methanolysis of Ammonia Borane to Produce Hydrogen