Strategies and Perspectives to Catch the Missing Pieces in Energy‐Efficient Hydrogen Evolution Reaction in Alkaline Media

Anantharaj, Sengeni; Noda, Suguru; Jothi, Vasanth Rajendiran; Yi, Sung Chul; Drieß, Matthias; Menezes, Prashanth W.

doi:10.1002/ange.202015738

Cited by 33 publications

(30 citation statements)

References 157 publications

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“…[11][12][13] Within them, electrocatalytic water splitting has become the worldwide research focus recently as this technology can produce environmental-friendly highpure H 2 energy from electricity, as well as can be combined with other intermittent energy, such as wind and solar energy, elevating the utilization efficiency of the overall sustainable energy system. [14,15] The fundamental half-reactions which take place on a water electrolyzer involve hydrogen evolution reaction (HER) at the cathode and oxygen evolution reaction (OER) at the anode. [16] Presently, the commercial devices for water electrolysis include acidic proton-exchange membranes (PEMs) electrolyzer and alkaline water electrolyzers (AWEs).…”

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confidence: 99%

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Yang

Drieß

Menezes

2021

Advanced Energy Materials

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207

146

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Over the years, significant advances have been made to boost the efficiency of water splitting by carefully designing economic electrocatalysts with augmented conductivity, more accessible active sites, and high intrinsic activity in laboratory test conditions. However, it remains a challenge to develop earth‐abundant catalysts that can satisfy the demands of practical water electrolysis, that is, outstanding all‐pH electrolyte capacity, direct seawater splitting ability, exceptional performance for overall water splitting, superior large‐current‐density activity, and robust long‐term durability. In this context, considering the features of increased active species loading, rapid charge, and mass transfer, a strong affinity between catalytic components and substrates, easily‐controlled wettability, as well as, enhanced bifunctional performance, the self‐supported electrocatalysts are presently projected to be the most suitable contenders for practical massive scale hydrogen generation. In this review, a comprehensive introduction to the design and fabrication of self‐supported electrocatalysts with an emphasis on the design of deposited nanostructured catalysts, the selection of self‐supported substrates, and various fabrication methods are provided. Thereafter, the recent development of promising self‐supported electrocatalysts for practical applications is reviewed from the aforementioned aspects. Finally, a brief conclusion is delivered and the challenges and perspectives relating to promotion of self‐supported electrocatalysts for sustainable large‐scale production of hydrogen are discussed.

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mentioning

confidence: 99%

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Yang

Drieß

Menezes

2021

Advanced Energy Materials

Self Cite

207

146

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“…While the HER is a relatively straightforward two-electron transfer process, the main bottleneck is the sluggish four-electron OER that limits the overall efficiency of water electrolysis. [2,3] Currently, the common and matured industrialized electrolyzers to produce hydrogen rely on either acidic (proton-exchange membrane) or alkaline conditions. Out of which, alkaline electrolyzers are of particular importance as they use low-cost and earth-abundant materials to make the system fully sustainable and economically competitive.…”

mentioning

confidence: 99%

Nanostructured Intermetallic Nickel Silicide (Pre)Catalyst for Anodic Oxygen Evolution Reaction and Selective Dehydrogenation of Primary Amines

Mondal

Hausmann

Vijaykumar

et al. 2022

Advanced Energy Materials

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Water electrolysis consists of two electrochemical half-reactions: the hydrogen evolution reaction (HER) to produce hydrogen at the cathode and the OER to evolve oxygen at the anode, respectively. While the HER is a relatively straightforward two-electron transfer process, the main bottleneck is the sluggish four-electron OER that limits the overall efficiency of water electrolysis. [2,3] Currently, the common and matured industrialized electrolyzers to produce hydrogen rely on either acidic (proton-exchange membrane) or alkaline conditions. Out of which, alkaline electrolyzers are of particular importance as they use low-cost and earth-abundant materials to make the system fully sustainable and economically competitive. [4] As stated above, in order to increase the efficiency of the electrolyzers, improved anodes with high intrinsic activity are required. Notably, for alkaline electrolyzers, Ni-based materials have been the typical choice as anode (OER) materials because of their cost-effectiveness, high elemental abundance, good resistance to corrosive solutions, and low toxicity. [5,6] In recent years, significant progress has been achieved in the design, synthesis, and development of a variety of highly efficient Ni-based electrocatalysts involving oxides/hydroxides, chalcogenides, pnictides, alloys, and even metal-organic frameworks for OER at the lab scale to minimize the energetic losses in alkaline electrolysis. [6][7][8][9][10][11] Besides, significant efforts have been made to modify Ni-based electrocatalysts through heterostructure formation, oxygendefect generation, doping with heteroatoms, as well as phase and morphology engineering to attain technically viable efficiencies. However, further improvement beyond the current state of the art is required to enhance the overall OER performance. [9][10][11][12][13][14] Most of the Ni-based catalysts transform under the electrochemical alkaline conditions into electronically similar layered oxyhydroxide (LOH) phase with Ni III O x H y structure. [15,16] Similar to other transition-metal electrocatalysts, the OER activity of Ni-based catalysts largely depends on the defects, surface area, morphology, crystal structure of the precatalyst (e.g., NiNi distances), amount of edge/corner-sharing [NiO 6 ] units, size of the crystallite domain, etc. of the transformed Ni III O x H y phases,The development of novel earth-abundant metal-based catalysts to accelerate the sluggish oxygen evolution reaction (OER) is crucial for the process of large-scale production of green hydrogen. To solve this bottleneck, herein, a simple one-pot colloidal approach is reported to yield crystalline intermetallic nickel silicide (Ni 2 Si), which results in a promising precatalyst for anodic OER. Subsequently, an anodic-coupled electrosynthesis for the selective oxidation of organic amines (as sacrificial proton donating agents) to value-added organocyanides is established to boost the cathodic reaction. A partial transformation of the Ni 2 Si intermetallic precatalyst generates a poro...

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“…The flexibility of most carbon-based materials promotes high-efficiency interface compatibility when combined with other materials and further leads to excellent migration ability of interface electrons. [191] The latest research is mainly about the doping system of graphene and its derivatives. The introduction of defect states enhances the electron transport of low-dimensional materials as expected.…”

Section: Non-metal-based Heterogeneous Catalystsmentioning

confidence: 99%

A Review of the Application of Heterostructure Catalysts in Hydrogen Evolution Reaction

Dong

Zhao

et al. 2022

ChemistrySelect

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Hydrogen energy as a significant part of clean energy in the future has been widely studied. Hydrogen production from electric cracking water is the most effective and mature development method at present. Heterostructured electrocatalysts are favored due to their low overpotential, excellent assembly structure and good electron transfer ability. Consequently this paper reviews the development of heteroge-neous electrocatalysts, the measurement parameters of electrocatalytic hydrogen evolution reaction (HER), and related research progress, and gives the hydrogen evolution mechanism in acidic, alkaline and neutral environments. Finally, we explain the essential development direction and severe challenges in this field.

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Strategies and Perspectives to Catch the Missing Pieces in Energy‐Efficient Hydrogen Evolution Reaction in Alkaline Media

Cited by 33 publications

References 157 publications

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Self‐Supported Electrocatalysts for Practical Water Electrolysis

Nanostructured Intermetallic Nickel Silicide (Pre)Catalyst for Anodic Oxygen Evolution Reaction and Selective Dehydrogenation of Primary Amines

A Review of the Application of Heterostructure Catalysts in Hydrogen Evolution Reaction

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