A theoretical study on the enhanced oxygen evolution performance of NiN<sub>4</sub>-graphene by Ni nanoclusters

Shi, Runchuan; Feng, Shihao; Fu, Zhaoming; Yang, Zongxian; Zhang, Xilin

doi:10.1088/1361-6463/ad297c

J. Phys. D: Appl. Phys.

2024

DOI: 10.1088/1361-6463/ad297c

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A theoretical study on the enhanced oxygen evolution performance of NiN₄-graphene by Ni nanoclusters

Runchuan Shi,

Shihao Feng,

Zhaoming Fu

et al.

Abstract: Isolated metal-coordinated nitrogen embedded carbon (M-N-C) materials are potential alternatives to noble catalysts for oxygen evolution reaction (OER), and the activity of metal centers can be further modulated by adjusting the coordination environment. Recently, experimental studies have shown that the aggregation of metal atoms into small clusters or particles is inevitable during the high temperature pyrolysis, while the influences of metal clusters on the OER activity of single metal atoms in M-N-C are un… Show more

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Cited by 3 publications

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A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

Ma,

Xiong,

Wang

et al. 2024

Materials Today Sustainability

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A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

Ma,

Xiong,

Wang

et al. 2024

Materials Today Sustainability

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Effect of charge state on alkaline OER activity in FeN₄–Gr catalyst supported on Ni (111) substrate

Wang,

Zhang,

Zhang

et al. 2024

J. Phys. D: Appl. Phys.

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The catalysts of transition metal single−atom embedded in N−doped graphene (TMN4−Gr) have attracted significant attention due to the high utilization of transition metal atoms, remarkable selectivity and tunable catalytic activity. In this study, we have employed first−principles study to investigate alkaline OER activity of FeN4−Gr system supported on a Ni (111) substrate (FeN4−Gr/Ni). The results show that the Ni substrate can significantly enhance the OER activity of FeN4−Gr catalyst. The overpotential of FeN4−Gr/Ni catalyst is 0.63 V, much lower than 0.79 V of the FeN4−Gr, which is closely related to the strong interaction from the Ni substrate. By subtracting electrons from the FeN4−Gr/Ni catalyst, a positive charge environment can be created. It is found that, between the FeN4−Gr and the Ni substrate, a significant electron transfer phenomenon is observed, and the amount can be regulated by the charge state. Besides, the charge state can obviously tune the adsorption strength of *OOH intermediate through the interaction of Ni substrate, further optimizing the OER activity thermodynamically favorable. As the charge state increases to +1.55, the overpotential decreases to 0.23 V. By analyzing the integrated crystal orbital Hamilton populations, the chemical bond strength of Fe−O is discussed. Our results reveal that the Ni substrate can significantly enhance the OER activity of the FeN4−Gr catalyst, and the charge state can also tune the overpotential, offering valuable insights for the design of high−efficiency single−atom catalysts utilizing metal substrate.

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Editorial for design of nanocluster-based functional materials

Wang,

Xu,

et al. 2024

J. Phys. D: Appl. Phys.

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Ultrasmall nanoparticles, universally recognized as nanoclusters, exhibit distinctive physical and chemical properties that are typically unobservable in bulk materials, stemming from the profound quantum confinement effects. With significant breakthroughs in crystal structure determination and atomically precise synthesis, nanoclusters have garnered increasing attention due to their intriguing luminescence properties, electronic transitions between highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital (LUMO), chirality, quantized charging capabilities, and magnetic behaviors, along with their promising applications in diverse fields such as energy storage and conversion, catalysis, environmental remediation, and biological medicine. Furthermore, cluster assembly offers a promising route to fabricate innovative materials endowed with captivating properties, thereby offering novel approaches for designing nanocluster-based functional materials. Combining nanoclusters with one-dimensional (1D), two-dimensional (2D), and three-dimensional (3D) substrates to form composites usually introduce unusual physicochemical properties that are notably distinct from individual substrates and nanoclusters. Notably, the physicochemical properties of composites constructed by nanoclusters and 1D (or 2D) substrates can be readily tuned by the application of strain or an electric field, offering another additional avenue for designing nanocluster-based functional materials.In the Special Issue of Journal of Physics D: Applied Physics, entitled “Design of Nanocluster-Based Functional Materials”, we’ve compiled a comprehensive collection of 19 articles, showcasing the latest advancements in the field of cluster design and assembly, cluster adsorption and catalysis, and low-dimensional material devices. In the following, we concisely summarized the key research highlights of these studies.

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A theoretical study on the enhanced oxygen evolution performance of NiN₄-graphene by Ni nanoclusters

Cited by 3 publications

References 41 publications

A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

Effect of charge state on alkaline OER activity in FeN₄–Gr catalyst supported on Ni (111) substrate

Editorial for design of nanocluster-based functional materials

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A theoretical study on the enhanced oxygen evolution performance of NiN4-graphene by Ni nanoclusters

Cited by 3 publications

References 41 publications

A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

A review of advancements in theoretical simulation of oxygen reduction reaction and oxygen evolution reaction single-atom catalysts

Effect of charge state on alkaline OER activity in FeN4–Gr catalyst supported on Ni (111) substrate

Editorial for design of nanocluster-based functional materials

Contact Info

Product

Resources

About

A theoretical study on the enhanced oxygen evolution performance of NiN₄-graphene by Ni nanoclusters

Effect of charge state on alkaline OER activity in FeN₄–Gr catalyst supported on Ni (111) substrate