Your search keyword '"Ou-Yang, Zhen-Yang"' showing total 4 results

1. Ultrafast synthesis of biphase Ni-doped FeOOH for efficient and stable oxygen evolution at high current density.

Author

Xie, Meng-Yuan, Wan, Hui, Nie, Jianhang, Xian, Ming-Hua, Ou-Yang, Zhen-Yang, Huang, Jia-Rong, Huang, Gui-Fang, and Huang, Wei-Qing

Subjects

OXYGEN evolution reactions, OXIDATION of water, OXIDATION-reduction reaction, HETEROJUNCTIONS, ELECTROLYSIS, ELECTROCATALYSTS

Abstract

NiFe oxyhydroxides, generally reconstructed on surface during oxygen evolution reaction (OER), are real active species for water oxidation; however, their direct and convenient preparation remains challenging. Here, we develop a one-step approach to prepare biphase (α/δ) Ni-doped FeOOH catalyst in 3 min under room temperature. The core of this ultrafast method is that Fe2+ derived from the redox reaction of Fe3+ and Ni2+ accelerate Fenton-like reaction, while simultaneously producing mixed-valence Ni ions(Ni2+, Ni3+) results in not only homovalent and heterovalent doping, but also biphase Ni-doped FeOOH heterojunction with high and low crystallinity. Specifically, Ni2+ doping leads to a preferred formation of low-crystalline δ-oriented Ni-doped FeOOH with abundant oxygen vacancies, which is in favor of triggering the lattice oxygen mechanism (LOM) during OER. Benefitting from high/low crystalline biphase heterojunction and LOM, the optimized Ni-FeOOH merely needs low overpotential of 300 mV to reach 1000 mA cm−2 for OER in alkaline electrolyte and also shows excellent durability even at a high current density of 500 mA cm−2. This work provides a cost-effective strategy to fabricate highly active and robust non-noble electrocatalysts that can potentially be applied for industrial-scale OER electrolysis. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cooperative coupling of microscopic enhanced electric field and macroscopic efficient bubble traffic for industrial hydrogen evolution.

Author

Ou-Yang, Zhen-Yang, Nie, Jianhang, Xia, Sheng-Xuan, Xie, Meng-Yuan, Xian, Ming-Hua, Wan, Hui, Huang, Gui-Fang, and Huang, Wei-Qing

Subjects

*INTERSTITIAL hydrogen generation, *ELECTRIC fields, *BUBBLE dynamics, *HYDROGEN atom, *ENERGY storage

Abstract

The alkaline hydrogen evolution reaction (HER) for industrial hydrogen generation is a promising way to achieve intermittent energy storage. However, challenges, such as the insufficient supply of adsorbed hydrogen atoms (*H) and slow bubble dynamics, hinder the development of industrial HER. Here, we report a cooperative strategy by leveraging both microscopic enhanced electric field and macroscopic efficient bubble traffic for industrial hydrogen evolution, demonstrated through the NiCoP nanotips on NiP nanorods (NiCoP-tip@NiP). Specifically, during the HER process, the nanotips can accumulate a large number of electrons, enhancing the electric field of the Stern layer. This enhanced electric field accelerates the dissociation of water, resulting in favorable *H for HER. Simultaneously, the confined space between the nanotips hinders the growth of bubbles generated at the tips. Newly formed bubbles will push out the existing bubbles, thus accelerating gas release. As a result, NiCoP-tip@NiP exhibits a low overpotential of 300 mV at 1000 mA cm−2 and maintains stable operation over 90 h at approximately 300 mA cm−2 during HER processes. This cooperative strategy provides profound insights for industrial hydrogen generation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Cation-induced formation of highly active γ-NiFeOOH for efficient oxygen evolution reaction.

Author

Ou-Yang, Zhen-Yang, Nie, Jianhang, Xie, Meng-Yuan, Xian, Ming-Hua, Shi, Jinghui, Wan, Hui, Huang, Gui-Fang, and Huang, Wei-Qing

Subjects

*OXYGEN evolution reactions, *PHOTOCATHODES, *DOPING agents (Chemistry)

Abstract

The oxygen evolution reaction (OER) activity of Ni-based oxyhydroxides greatly hinges on their phase structures, which are mainly γ and β phases: the former has higher intrinsic activity than the latter. However, it is still a grand challenge to purposefully generate γ phase, rather than β phase. Here, we propose a cation-doping strategy to generate γ phase by taking Zn-doped NiFeP/N-doped C (Z-NFP/N-C) precatalyst as a model. In contrast to the case of NFP/N-C that can only be reconstructed into β-NiFeOOH, Zn dopant will induce the formation of γ-NiFeOOH during an electrochemical process. Specifically, the doped Zn cation will promote the dissolution of NiFeP and redeposition of NiFeOOH on the surface. Simultaneously, the cation defects generated by Zn leaching will force the surrounding Ni valence state to rise for charge balance and will attract more K+ in the solution to intercalate into the interlayer of NiFeOOH, resulting in the formation of γ-NiFeOOH. As a result, the γ-NiFeOOH/Z-NFP/N-C exhibits superior OER performance: a low overpotential of 216 mV at 10 mA cm−2 and satisfactory stability (100 h at 17 mA cm−2). Our study offers a practical approach to produce highly active "true catalyst" for efficient water splitting. [ABSTRACT FROM AUTHOR]

Published

2024

4. Boosting cascade electron transfer in NiFe oxyhydroxide for overall water splitting.

Author

Xian, Ming-Hua, Wan, Hui, Wang, Qiao-Ling, Xie, Meng-Yuan, Shi, Jinghui, Nie, Jianhang, Li, Bo, Ou-Yang, Zhen-Yang, Huang, Jia-Rong, Wang, Di, Huang, Gui-Fang, Hu, Wangyu, and Huang, Wei-Qing

Subjects

CHARGE exchange, OXYGEN evolution reactions, CHARGE transfer, ENERGY consumption

Abstract

Nickel–iron oxyhydroxides are among the most active electrocatalysts, but their sluggish kinetic of oxygen evolution reaction (OER) limits the energy efficiency toward overall water splitting. Here, we present a "cascade electron transfer" strategy through spurring unidirectional electron transfer among different metal sites in Mn-doped FeNiOOH@FeNiP to boost OER and overall water splitting. The Mn doping induces a cascade electron transfer from Ni to Fe and then to Mn via metal-O-metal bridge, thus promoting the oxidation Ni and Fe centers, which in turn help charge transfer by increasing the covalency between metal-O bonds to optimize the bonding strength between metal and adsorbed oxygen species. Consequently, the optimal Mn–FeNiOOH@FeNiP delivers a fast OER kinetics (32.1 mV dec−1) along with a low overpotential of 215 mV@10 mA cm−2. Benefiting from the synergistic effect of high conductivity, large specific surface area, and favorable OER kinetics, the catalyst only requires a low cell voltage of 1.456 V to achieve 20 mA cm−2 for overall water splitting, superior to that of a commercial RuO2ǁPt/C catalyst. [ABSTRACT FROM AUTHOR]

Published

2024