Triple Functions of Ni(OH)<sub>2</sub> on the Surface of WN Nanowires Remarkably Promoting Electrocatalytic Activity in Full Water Splitting

Lv, Cuncai; Wang, Xiaobo; Gao, Linjie; Wang, Aijian; Wang, Shufang; Wang, Ruining; Ning, Xiaojuan; Li, Yaguang; Boukhvalov, Danil W.; Huang, Zhipeng; Zhang, Chi

doi:10.1021/acscatal.0c02891

Cited by 126 publications

(68 citation statements)

References 66 publications

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“…In the Ni 2p spectra, Ni 2p 1/2 and Ni 2p 3/2 are detected for both samples. The peak positions of the Ni 2p 1/2 and Ni 2p 3/2 bands appear at 872 and 855 eV, respectively, which is consistent with the divalent nickel pattern and indicates that Ni is present as Ni(OH) 2 . , The peak position of Fe 2p 3/2 for Ni5(Fe5/Ni5) 1 (710 eV) is attributable to the intermediate position of the Fe 2+ and Fe 3+ states. , Thus, Fe 2+ remains in the as-deposited film, while partial oxidation to Fe 3+ occurred during the deposition and/or after exposure to air. Thus, the actual chemical composition of the product deviates from FeOOH.…”

Section: Resultssupporting

confidence: 56%

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties

Taniguchi

Kubota

Matsushita

et al. 2021

ACS Appl. Energy Mater.

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The use of nanoscale heterostructures is an effective approach for developing catalysts that are free of precious metals for sustainable energy conversion. In this study, a sequenced successive ionic layer adsorption and reaction (sequenced-SILAR) method was developed for the fabrication of Ni(OH)2/FeOOH heterostructures. In this method, the order of the deposition cycles of individual Ni(OH)2 and FeOOH layers was programmed to control the thickness and stacking order of these layers in the heterostructure. The sequenced-SILAR process using an Fe2+ solution as the iron source produced dense heterojunctions offering overpotentials of 330 and 234 mV at 10 mA cm–2 for an oxygen evolution reaction (OER) on a flat, conducting oxide substrate and porous Ni foam, respectively. Investigation of the deposition-sequence-dependent OER activity indicated that the Ni(OH)2/FeOOH coupling effects may extend to the Ni2+ active sites located about 10 nm from the heterointerface. When an Fe3+ precursor was employed in the sequenced-SILAR process, dense heterojunctions were not produced because of the formation of isolated FeOOH particles. As a result, an excellent overpotential was not obtained. In principle, the sequenced-SILAR method can be extended to the fabrication of various types of heterostructures. However, the deposition conditions must be carefully designed to offer strong interfacial coupling effects.

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Section: Resultssupporting

confidence: 56%

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties

Taniguchi

Kubota

Matsushita

et al. 2021

ACS Appl. Energy Mater.

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“…Tungsten-based nitrides and their combinations with reduced graphene oxide (rGO) [ 219 ], bimetallic nitrides [ 220 ], metal doping [ 221 ], metal carbides [ 222 ], and metal hydroxides [ 223 ] have been extensively used as electrocatalysts for HER. For example, Yan et al demonstrated that even a small amount (2.52 at%) of phosphorus doping can greatly enhance the HER activity of WN/rGO as it significantly alters the electronic state and increases the electron density and the active sites of the material [ 219 ].…”

Section: Electrochemical Production Of Hydrogenmentioning

confidence: 99%

Metal nitride-based nanostructures for electrochemical and photocatalytic hydrogen production

Gujral

Singh

Baskar

et al. 2022

Science and Technology of Advanced Materials

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The over-dependence on fossil fuels is one of the critical issues to be addressed for combating greenhouse gas emissions. Hydrogen, one of the promising alternatives to fossil fuels, is renewable, carbon-free, and non-polluting gas. The complete utilization of hydrogen in every sector ranging from small to large scale could hugely benefit in mitigating climate change. One of the key aspects of the hydrogen sector is its production via cost-effective and safe ways. Electrolysis and photocatalysis are well-known processes for hydrogen production and their efficiency relies on electrocatalysts, which are generally noble metals. The usage of noble metals as catalysts makes these processes costly and their scarcity is also a limiting factor. Metal nitrides and their porous counterparts have drawn considerable attention from researchers due to their good promise for hydrogen production. Their properties such as active metal centres, nitrogen functionalities, and porous features such as surface area, pore-volume, and tunable pore size could play an important role in electrochemical and photocatalytic hydrogen production. This review focuses on the recent developments in metal nitrides from their synthesis methods point of view. Much attention is given to the emergence of new synthesis techniques, methods, and processes of synthesizing the metal nitride nanostructures. The applications of electrochemical and photocatalytic hydrogen production are summarized. Overall, this review will provide useful information to researchers working in the field of metal nitrides and their application for hydrogen production.

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“…In consideration of saving energy and protecting the environment, electrocatalysis water splitting is an efficient and clean approach to obtain high-purity hydrogen gas as one of the most potential alternatives for future energy. − As a candidate for Pt-based catalysts, low-cost and high-activity electrocatalysts urgently need to be developed for satisfying the requirement of consuming hydrogen energy in a large scale. , The current research on electrocatalysts for the hydrogen evolution reaction (HER) is mainly focused on the synthesis and modification of non-precious-metal-based compounds such as transition-metal oxides, nitrides, and carbides. − The rational design of catalysts plays a significant role in reducing the activation energy of the reaction to improve the reaction rate and energy conversion efficiency . Based on the Sabatier principle, the hydrogen adsorption energy on catalyst surface should be moderate, too strong to desorb active intermediates, or too weak to activate reactants .…”

Section: Introductionmentioning

confidence: 99%

From Hexagonal to Monoclinic: Engineering Crystalline Phase to Boost the Intrinsic Catalytic Activity of Tungsten Oxides for the Hydrogen Evolution Reaction

Yang

Chen

Liu

et al. 2021

ACS Sustainable Chem. Eng.

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The intrinsic activity of catalysts is crucial for the electrocatalytic hydrogen evolution reaction, which is essentially dependent on their crystal structure and surface electronic state. The variable crystalline phase in tungsten oxide (WO 3 ) can provide a favorable opportunity for modulating surface electronic state. In this work, the structure−activity relationship of the representative hexagonal and monoclinic phase WO 3 (h-WO 3 and m-WO 3 ) for the hydrogen evolution reaction was discussed in detail by experimental techniques combined with density functional theory (DFT) calculations. DFT calculations reveal that m-WO 3 exhibits the modest H-adsorption/desorption energy, which is beneficial to the fast desorption of active H* intermediate compared to h-WO 3 , displaying superior catalytic activity in the hydrogen evolution reaction. To accelerate the charge transfer, introduction of reduced graphene oxide (rGO) further amplifies the intrinsic catalytic activity endowed with this crystalline phase. In acid media, the m-WO 3 /rGO catalyst shows a low Tafel slope of 32 mV dec −1 , requires an overpotential of only 35 mV to drive a current density of 10 mA cm −2 , and keeps excellent stability during accelerated durability test. This work presents significance of crystalline phase for optimizing the intrinsic activity of catalyst and provides a novel idea to design a high-efficient catalyst for the hydrogen evolution reaction.

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Triple Functions of Ni(OH)₂ on the Surface of WN Nanowires Remarkably Promoting Electrocatalytic Activity in Full Water Splitting

Cited by 126 publications

References 66 publications

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties

Metal nitride-based nanostructures for electrochemical and photocatalytic hydrogen production

From Hexagonal to Monoclinic: Engineering Crystalline Phase to Boost the Intrinsic Catalytic Activity of Tungsten Oxides for the Hydrogen Evolution Reaction

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Triple Functions of Ni(OH)2 on the Surface of WN Nanowires Remarkably Promoting Electrocatalytic Activity in Full Water Splitting

Cited by 126 publications

References 66 publications

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)2/FeOOH Heterostructures with Tailored Catalytic Properties

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)2/FeOOH Heterostructures with Tailored Catalytic Properties

Metal nitride-based nanostructures for electrochemical and photocatalytic hydrogen production

From Hexagonal to Monoclinic: Engineering Crystalline Phase to Boost the Intrinsic Catalytic Activity of Tungsten Oxides for the Hydrogen Evolution Reaction

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Triple Functions of Ni(OH)₂ on the Surface of WN Nanowires Remarkably Promoting Electrocatalytic Activity in Full Water Splitting

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties

Sequenced Successive Ionic Layer Adsorption and Reaction for Rational Design of Ni(OH)₂/FeOOH Heterostructures with Tailored Catalytic Properties