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1. Enhanced Electrocatalytic Hydrogen Oxidation on Ni/NiO/C Derived from a Nickel‐Based Metal–Organic Framework

   https://doi.org/10.1002/anie.201905430  

   Yang, Yang ; Sun, Xiaodong ; Han, Guanqun ; Liu, Xi ; Zhang, Xiangyu ; Sun, Yongfang ; Zhang, Min ; Cao, Zhi ; Sun, Yujie ( June 2019 , Angewandte Chemie International Edition)

   The sluggish hydrogen oxidation reaction (HOR) under alkaline conditions has hindered the commercialization of hydroxide‐exchange membrane hydrogen fuel cells. A low‐cost Ni/NiO/C catalyst with abundant Ni/NiO interfacial sites was developed as a competent HOR electrocatalyst in alkaline media. Ni/NiO/C exhibits an HOR activity one order of magnitude higher than that of its parent Ni/C counterpart. Moreover, Ni/NiO/C also shows better stability and CO tolerance than commercial Pt/C in alkaline media, which renders it a very promising HOR electrocatalyst for hydrogen fuel cell applications. Density functional theory (DFT) calculations were also performed to shed light on the enhanced HOR performance of Ni/NiO/C; the DFT results indicate that both hydrogen and hydroxide achieve optimal binding energies at the Ni/NiO interface, resulting from the balanced electronic and oxophilic effects at the Ni/NiO interface.

    

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2. A completely precious metal–free alkaline fuel cell with enhanced performance using a carbon-coated nickel anode

   https://doi.org/10.1073/pnas.2119883119  

   Gao, Yunfei ; Yang, Yao ; Schimmenti, Roberto ; Murray, Ellen ; Peng, Hanqing ; Wang, Yingming ; Ge, Chuangxin ; Jiang, Wenyong ; Wang, Gongwei ; DiSalvo, Francis J. ; et al ( March 2022 , Proceedings of the National Academy of Sciences)

   Alkaline fuel cells enable the use of earth-abundant elements to replace Pt but are hindered by the sluggish kinetics of the hydrogen oxidation reaction (HOR) in alkaline media. Precious metal–free HOR electrocatalysts need to overcome two major challenges: their low intrinsic activity from too strong a hydrogen-binding energy and poor durability due to rapid passivation from metal oxide formation. Here, we designed a Ni-based electrocatalyst with a 2-nm nitrogen-doped carbon shell (Ni@CN x ) that serves as a protection layer and significantly enhances HOR kinetics. A Ni@CN x anode, paired with a Co−Mn spinel cathode, exhibited a record peak power density of over 200 mW/cm 2 in a completely precious metal–free alkaline membrane fuel cell. Ni@CN x exhibited superior durability when compared to a Ni nanoparticle catalyst due to the enhanced oxidation resistance provided by the CN x layer. Density functional theory calculations suggest that graphitic carbon layers on the surface of the Ni nanoparticles lower the H binding energy to Ni, bringing it closer to the previously predicted value for optimal HOR activity, and single Ni atoms anchored to pyridinic or pyrrolic N defects of graphene can serve as the HOR active sites. The strategy described here marks a milestone in electrocatalyst design for low-cost hydrogen fuel cells and other energy technologies with completely precious metal–free electrocatalysts. 

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3. Hydrogenated TiO 2 Carbon Support for PtRu Anode Catalyst in High‐Performance Anion‐Exchange Membrane Fuel Cells

   https://doi.org/10.1002/smll.202307497  

   Douglin, John C. ; Sekar, Archana ; Singh, Ramesh K. ; Chen, Zihua ; Li, Jun ; Dekel, Dario R. ( December 2023 , Small)

   The availability of durable, high‐performance electrocatalysts for the hydrogen oxidation reaction (HOR) is currently a constraint for anion‐exchange membrane fuel cells (AEMFCs). Herein, a rapid microwave‐assisted synthesis method is used to develop a core–shell catalyst support based on a hydrogenated TiO₂/carbon for PtRu nanoparticles (NPs). The hydrogenated TiO₂provides a strong metal‐support interaction with the PtRu NPs, which improves the catalyst's oxophilicity and HOR activity compared to commercial PtRu/C and enables greater size control of the catalyst NPs. The as‐synthesized PtRu/TiO₂/C‐400 electrocatalyst exhibits respectable performance in an AEMFC operated at 80 °C, yielding the highest current density (up to 3× higher) within the catalytic region (compared at 0.80–0.90 V) and voltage efficiency (68%@ 0.5 A cm⁻²) values in the compared literature. In addition, the cell demonstrates promising short‐term voltage stability with a minor voltage decay of 1.5 mV h⁻¹. This “first‐of‐its‐kind in alkaline” work may open further research avenues to develop rapid synthesis methods to prepare advanced core–shell metal‐oxide/carbon supports for electrocatalysts for use in the next‐generation of AEMFCs with potential applicability to the broader electrochemical systems research community.

    

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4. Solar-driven, highly sustained splitting of seawater into hydrogen and oxygen fuels

   https://doi.org/10.1073/pnas.1900556116  

   Kuang, Yun ; Kenney, Michael J. ; Meng, Yongtao ; Hung, Wei-Hsuan ; Liu, Yijin ; Huang, Jianan Erick ; Prasanna, Rohit ; Li, Pengsong ; Li, Yaping ; Wang, Lei ; et al ( March 2019 , Proceedings of the National Academy of Sciences)

   Electrolysis of water to generate hydrogen fuel is an attractive renewable energy storage technology. However, grid-scale freshwater electrolysis would put a heavy strain on vital water resources. Developing cheap electrocatalysts and electrodes that can sustain seawater splitting without chloride corrosion could address the water scarcity issue. Here we present a multilayer anode consisting of a nickel–iron hydroxide (NiFe) electrocatalyst layer uniformly coated on a nickel sulfide (NiSx) layer formed on porous Ni foam (NiFe/NiSx-Ni), affording superior catalytic activity and corrosion resistance in solar-driven alkaline seawater electrolysis operating at industrially required current densities (0.4 to 1 A/cm²) over 1,000 h. A continuous, highly oxygen evolution reaction-active NiFe electrocatalyst layer drawing anodic currents toward water oxidation and an in situ-generated polyatomic sulfate and carbonate-rich passivating layers formed in the anode are responsible for chloride repelling and superior corrosion resistance of the salty-water-splitting anode.

    

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5. Steering Elementary Steps towards Efficient Alkaline Hydrogen Evolution via Size-Dependent Ni/NiO Nanoscale Heterosurfaces

   https://doi.org/10.1093/nsr/nwz145  

   Zhao, Lu ; Zhang, Yun ; Zhao, Zhonglong ; Zhang, Qing-Hua ; Huang, Lin-Bo ; Gu, Lin ; Lu, Gang ; Hu, Jin-Song ; Wan, Li-Jun ( October 2019 , National Science Review)

   Alkaline hydrogen evolution reaction (HER), consisted of Volmer and Heyrovsky/Tafel steps, requires extra energy for water dissociation, leading to more sluggish kinetics than acidic HER. Despite the advances in electrocatalysts, how to combine active sites to synergistically promote both steps and understand the underlying mechanism remain largely unexplored. Here, DFT calculations predict that NiO accelerates Volmer step while metallic Ni facilitates Heyrovsky/Tafel step. A facile strategy is thus developed to control Ni/NiO heterosurfaces in uniform and well-dispersed Ni-based nanocrystals, targeting both reaction steps synergistically. By systematically modulating the surface composition, we find that steering the elementary steps through tuning the Ni/NiO ratio can significantly enhance alkaline HER activity and Ni/NiO nanocrystals with a Ni/NiO ratio of 23.7% deliver the best activity, outperforming other state-of-the-art analogues. The results suggest that integrating bicomponent active sites for elementary steps is effective for promoting alkaline HER, but they have to be balanced.

    

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