Ni-Doping Effects on Oxygen Removal from an Orthorhombic Mo<sub>2</sub>C (001) Surface: A Density Functional Theory Study

Zhou, Mingxia; Cheng, Lei; Choi, Jae‐Soon; Liu, Bin; Curtiss, Larry A.; Assary, Rajeev S.

doi:10.1021/acs.jpcc.7b09870

Cited by 20 publications

(24 citation statements)

References 39 publications

(54 reference statements)

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“…Previous studies have demonstrated that the modification of electrocatalysts on molecular level can greatly enhance the thermodynamics and/or kinetics of electrocatalytic reactions, which can be achieved through rational designed synthetic process, such as constructing heterostructures, and transition‐metal doping . For example, V, Fe, Co, Ni, and Zn have been applied as dopants to modify the energy levels of catalysts, and improved their electrocatalytic activities. Recently, non‐3d high‐valence metals, such as Mo and W, were proved to be ideal dopants due to their unique advantages in optimizing Gibbs free energy (Δ G ) of formation of electrocatalytic intermediates, e.g., Δ G H* for HER and Δ G OH* for OER,7b,15 which paves a new path to boost performance of electrocatalyst.…”

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confidence: 99%

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Liu

Yin

et al. 2020

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Portable water splitting devices driven by rechargeable metal–air batteries or solar cells are promising, however, their scalable usages are still hindered by lack of suitable multifunctional electrocatalysts. Here, a highly efficient multifunctional electrocatalyst is demonstrated, i.e., 2D nanosheet array of Mo‐doped NiCo2O4/Co5.47N heterostructure deposited on nickel foam (Mo‐NiCo2O4/Co5.47N/NF). The successful doping of non‐3d high‐valence metal into a heterostructured nanosheet array, which is directly grown on a conductive substrate endows the resultant catalyst with balanced electronic structure, highly exposed active sites, and binder‐free electrode architecture. As a result, the Mo‐NiCo2O4/Co5.47N/NF exhibits remarkable catalytic activity toward the oxygen evolution reaction (OER) and hydrogen evolution reaction (HER), affording high current densities of 50 mA cm−2 at low overpotentials of 310 mV for OER, and 170 mV for HER, respectively. Moreover, a low voltage of 1.56 V is achieved for the Mo‐NiCo2O4/Co5.47N/NF‐based water splitting cell to reach 10 mA cm−2. More importantly, a portable overall water splitting device is demonstrated through the integration of a water‐splitting cell and two Zn–air batteries (open‐circuit voltage of 1.43 V), which are all fabricated based on Mo‐NiCo2O4/Co5.47N/NF, demonstrating a low‐cost way to generate fuel energy. This work offers an effective strategy to develop high‐performance metal‐doped heterostructured electrode.

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confidence: 99%

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Liu

Yin

et al. 2020

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“…can improve the catalytic performance by modulating the electronic configuration, producing new active sites and activating the surrounding sites. [ 88 ] Zhou et al [ 79 ] have investigated the role of “Ni” dopant atom toward the oxygen removal from the Mo 2 C (0 0 1) catalyst surface. The Bader charge analysis results showed that the charges values of Ni are −0.31 ( Figure ) and −0.16 (Figure 4b), corresponding the Ni‐adsorbed and Ni‐replaced on the Mo‐terminated Mo 2 C (0 0 1) surface, respectively.…”

Section: Active Surface/interfaces Engineering In Molybdenum Carbidementioning

confidence: 99%

“…Reproduced with permission. [ 79 ] Copyright 2018, American Chemical Society. e) SEM, f) TEM, and g) HR‐TEM images of Co‐Mo 2 C‐0.020 and h) their STEM images and the corresponding elemental mappings.…”

Section: Active Surface/interfaces Engineering In Molybdenum Carbidementioning

confidence: 99%

“…Heteroatom doping into materials lattice can tune the electronic or surface structures of the material and in turn influence the adsorption free energy of reaction intermediates on the surface for boosting the catalytic efficiency. [74,78,79] Heteroatom modification demonstrates that the additional heteroatoms replace the crystal lattice sites of material. The enhanced catalytic performance would be contributed to the optimized electronic configuration, which induced by the additional heteroatom element affecting the coordination environments of the surrounded elements in the composite.…”

Section: Heteroatom (S) Modificationmentioning

confidence: 99%

“…[100] Heterostructures, as a promising strategy for highly efficient electrochemical energy conversion, have been successfully applied in Mo x C-based catalytic materials, such as Reproduced with permission. [79] Copyright 2018, American Chemical Society. e) SEM, f) TEM, and g) HR-TEM images of Co-Mo 2 C-0.020 and h) their STEM images and the corresponding elemental mappings.…”

Section: Heterostructurementioning

confidence: 99%

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Surface and Interface Engineering: Molybdenum Carbide–Based Nanomaterials for Electrochemical Energy Conversion

Huo

Sun

et al. 2019

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Molybdenum carbide (MoxC)‐based nanomaterials have shown competitive performances for energy conversion applications based on their unique physicochemical properties. A large surface area and proper surface atomic configuration are essential to explore potentiality of MoxC in electrochemical applications. Although considerable efforts are made on the development of advanced MoxC‐based catalysts for energy conversion with high efficiency and stability, some urgent issues, such as low electronic conductivity, low catalytic efficiency, and structural instability, have to be resolved in accordance with their application environments. Surface and interface engineering have shown bright prospects to construct highly efficient MoxC‐based electrocatalysts for energy conversion including the hydrogen evolution reaction, oxygen evolution reaction, nitrogen reduction reaction, and carbon dioxide reduction reaction. In this Review, the recent progresses in terms of surface and interface engineering of MoxC‐based electrocatalytic materials are summarized, including the increased number of active sites by decreasing the particle size or introducing porous or hierarchical structures and surface modification by introducing heteroatom(s), defects, carbon materials, and others electronic conductive species. Finally, the challenges and prospects for energy conversion on MoxC‐based nanomaterials are discussed in terms of key performance parameters for the catalytic performance.

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In situ coupling of MnS-MoS2 bimetallic sulfide on nickel foam by [MnMo9O32]6− platform for advanced hydrogen evolution

Xiao

Khan

Cui

et al. 2023

Clean Techn Environ Policy

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Ni-Doping Effects on Oxygen Removal from an Orthorhombic Mo₂C (001) Surface: A Density Functional Theory Study

Cited by 20 publications

References 39 publications

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Surface and Interface Engineering: Molybdenum Carbide–Based Nanomaterials for Electrochemical Energy Conversion

In situ coupling of MnS-MoS2 bimetallic sulfide on nickel foam by [MnMo9O32]6− platform for advanced hydrogen evolution

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Ni-Doping Effects on Oxygen Removal from an Orthorhombic Mo2C (001) Surface: A Density Functional Theory Study

Cited by 20 publications

References 39 publications

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Non‐3d Metal Modulation of a 2D Ni–Co Heterostructure Array as Multifunctional Electrocatalyst for Portable Overall Water Splitting

Surface and Interface Engineering: Molybdenum Carbide–Based Nanomaterials for Electrochemical Energy Conversion

In situ coupling of MnS-MoS2 bimetallic sulfide on nickel foam by [MnMo9O32]6− platform for advanced hydrogen evolution

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Ni-Doping Effects on Oxygen Removal from an Orthorhombic Mo₂C (001) Surface: A Density Functional Theory Study