Rational Design of Ruthenium and Cobalt-Based Composites with Rich Metal–Insulator Interfaces for Efficient and Stable Overall Water Splitting in Acidic Electrolyte

Fan, Zehui; Jiang, Jing; Ai, Lunhong; Shao, Zongping; Liu, Shaomin

doi:10.1021/acsami.9b15844

Cited by 83 publications

(42 citation statements)

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“…A recently reported Ru-modified Co-based electrocatalyst, which was anchored in an N-doped carbon (NC) matrix and presented a rationally designed Mott−Schottky heterostructure (RuO 2 /Co 3 O 4 -RuCo@NC), achieved outstanding activity and stability for overall water splitting under strongly acidic conditions. [121] RuO 2 /Co 3 O 4 -RuCo@ NC was synthesized via a three-step process: pyrolysis of Co-MOF, galvanic replacement reaction between Co and Ru, and controlled partial oxidation. Notably, the composite with rich metal-semiconductor interfaces obtained by partial oxidation could promote the charge-transfer process; thus, the catalytic performance would be further improved.…”

Section: Metal-compound-doped Carbon Electrocatalystsmentioning

confidence: 99%

“…In recent times, a versatile strategy for designing highperformance electrocatalysts has been to controllably introduce two different metal species into a single nanostructure, namely Co-NC@ Mo 2 C, [119] Co 3 O 4 -RuCo@NC, [121] NG-NiFe@MoC 2 , [256] Co/Co 9 S 8 @ NSOC, [122] NiO/Co 3 O 4 , [120] Co@Ir/NC, [257] Ni 2 P/CoN-PCP, [258] among others, [92,[259][260][261][262][263][264] to further facilitate and accelerate the activation process of the reactants. For instance, Hu et al synthesized MoC 2 -doped NiFe alloy nanoparticles (NPs) embedded within several-layer-thick N-doped graphene (NG-NiFe@MoC 2 ) using one-step calcination of hybrid precursors composed of PVP-encapsulating NiFe-PBA and grafted Mo 6+ cations (Figure 15Ba).…”

Section: Mof-derived Catalystsmentioning

confidence: 99%

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Designing MOF Nanoarchitectures for Electrochemical Water Splitting

et al. 2021

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carrier with an extremely high energy density (approximately 142 MJ kg −1 ) and zero-carbon content, has been regarded as a promising clean fuel. [1,2] In this context, electrochemical water splitting, which converts electricity into storable hydrogen, is a viable and efficient solution to mitigate severe energy shortages and greenhouse gas emissions. [3] Among these strategies, hydrogen and oxygen evolution reactions, which occur on the cathode and anode, respectively, in a water electrolyzer, are considered as two critical half-reactions of the water-splitting process. [4] Theoretically, water splitting requires a thermodynamic Gibbs free energy (ΔG) of approximately 237.2 kJ mol −1 , corresponding to a standard potential (ΔE) of 1.23 V versus a reversible hydrogen electrode (RHE), which allows the thermodynamically uphill reaction to occur in the electrolyzer. [5] However, the unfavorable thermodynamics and resulting large overpotential are the main barriers to the scalable implementation of water electrolysis for hydrogen generation. [6,7] Currently, noble metal-based electrocatalysts exhibit the most efficient activity for water splitting, particularly Pt-based hydrogen evolution reaction (HER) catalysts and Ir/Ru-based oxygen evolution reaction (OER) catalysts. [8,9] Nevertheless, the scarcity and high price of precious metals severely impede their widespread use in commercial water-splitting applications. Taking these limitations into Electrochemical water splitting has attracted significant attention as a key pathway for the development of renewable energy systems. Fabricating efficient electrocatalysts for these processes is intensely desired to reduce their overpotentials and facilitate practical applications. Recently, metal-organic framework (MOF) nanoarchitectures featuring ultrahigh surface areas, tunable nanostructures, and excellent porosities have emerged as promising materials for the development of highly active catalysts for electrochemical water splitting. Herein, the most pivotal advances in recent research on engineering MOF nanoarchitectures for efficient electrochemical water splitting are presented. First, the design of catalytic centers for MOF-based/derived electrocatalysts is summarized and compared from the aspects of chemical composition optimization and structural functionalization at the atomic and molecular levels. Subsequently, the fast-growing breakthroughs in catalytic activities, identification of highly active sites, and fundamental mechanisms are thoroughly discussed. Finally, a comprehensive commentary on the current primary challenges and future perspectives in water splitting and its commercialization for hydrogen production is provided. Hereby, new insights into the synthetic principles and electrocatalysis for designing MOF nanoarchitectures for the practical utilization of water splitting are offered, thus further promoting their future prosperity for a wide range of applications.

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Section: Metal-compound-doped Carbon Electrocatalystsmentioning

confidence: 99%

Section: Mof-derived Catalystsmentioning

confidence: 99%

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

et al. 2021

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“…36,38,40 At the same time, related literature has also proven that the rich metal-insulator interface structure is benecial to improve the OER activity of Ru. 37,39 Therefore, it is hoped that both the Mott-Schottky effect will improve the charge transfer rate and the alloying will also optimize the electronic structure of Ru. This paper pays more attention to the preparation of the RuCo alloy base and the construction of the special surface morphology in the research method.…”

Section: Introductionmentioning

confidence: 99%

Nanostructured RuO₂–Co₃O₄@RuCo-EO with low Ru loading as a high-efficiency electrochemical oxygen evolution catalyst

et al. 2021

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“…Other works focused on preparation of HER active chalcogenides and hydroxides include Ni-Co sulfide/Ni-Co carbonate-hydroxide grown on Ni foam [95], MoS2@Ni(OH)2/Ni foam [96], Co9S8@MoS2 [97], Te@NiTe2/NiS [98], MoS2 coated Ni3S2 [99], WS2 supported on TiO2 [100], N-doped reduced graphene oxide supported CoSe2 [101], Co9S8 supported on N,S co-doped carbon [102], MoNiS@NiS [103], Mo-incorporated Ni(OH)2 [104], Ni2P-NiSe2 [105], NiCo2S4/CdO [106], Ni3S2 decorated by Ni3Sn2S2 quantum dots [107], metallic WSe2:Sn supported on reduced graphene oxide [108], and RuO2/Co3O4-RuCo supported on N-doped carbon [109].…”

Section: Supported Chalcogenides Hydroxides Pnictides and Carbidesmentioning

confidence: 99%

Hydrogen Evolution Reaction - From Single Crystal to Single Atom Catalysts

Gutić¹,

Dobrota²,

Fako³

et al. 2020

Preprint

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Hydrogen evolution reaction (HER) is one of the most important reaction in electrochemistry. This is not only because it is the simplest way to produce high purity hydrogen and the fact that it is the side reaction in many other technologies. HER actually shaped current electrochemistry because it was in focus of active research for so many years (and it still is). The number of catalysts investigated for HER is immense, and it is impossible to overview them all. In fact, it seems that the complexity of the field overcomes the complexity of HER. The aim of this review is to point out some of the latest developments in HER catalysis, current directions and some of the missing links between a single crystal, nanosized supported catalysts and, recently emerging, single atom catalysts for HER.3 of 36 HER at single crystal surfaces and bulk surfacesA crystalline solid can be considered as a series of mutually parallel lattice planes, arranged in a periodic way. Close to the surface, the spatial arrangement of the lattice planes, their crystallographic structure, as well as the dynamics of the constituent atoms may differ from the corresponding features in the bulk [1]. Most clean metals show the tendency to minimize their surface energy. One of the mechanisms is relaxation, the shift of one or more lattice planes located near to the surface, usually perpendicularly to the surface, so that the interlayer distance changes compared to the bulk lattice. The other one is reconstruction -change in equilibrium positions and bonding of surface atoms so that the projection of bulk unit cell to the given surface does not correspond to the surface unit cell. Different crystallographic planes (with different Miller indices) of the same metal exhibit unequal surface densities (number of atoms per surface area), and therefore undergo surface relaxation/reconstruction to different extents [2]. For example, Pt(100) has lower surface density compared to densely packed Pt(111) and therefore has a stronger tendency to relax/reconstruct. Since the main driving force for the mentioned surface modifications is the low coordination number (non-saturation) of surface atoms, it is obvious that atom/molecule adsorption on clean metal surfaces can have a significant effect on its surface structure, inducing relaxation/reconstruction changes. This is of huge importance for HER, as it involves adsorbed atomic hydrogen (Hads) as an intermediate. Additionally, in an electrochemical system, the electrode will be modified by adsorption of "spectator" species (ions/molecules from the electrolyte), so HER will not be taking place on clean metal surfaces, but rather on modified ones. Obviously, there is a complex dynamic interplay between the catalyst surface, reactants, intermediates, and electrolyte.According to the Sabatier principle, the interaction of the reaction reactants/intermediates with the catalyst has to be optimal in strength. If it is too weak, the reactants will not bind to the catalyst and the reaction will not be able to take place. In...

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Rational Design of Ruthenium and Cobalt-Based Composites with Rich Metal–Insulator Interfaces for Efficient and Stable Overall Water Splitting in Acidic Electrolyte

Cited by 83 publications

References 50 publications

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Nanostructured RuO₂–Co₃O₄@RuCo-EO with low Ru loading as a high-efficiency electrochemical oxygen evolution catalyst

Hydrogen Evolution Reaction - From Single Crystal to Single Atom Catalysts

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Rational Design of Ruthenium and Cobalt-Based Composites with Rich Metal–Insulator Interfaces for Efficient and Stable Overall Water Splitting in Acidic Electrolyte

Cited by 83 publications

References 50 publications

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Nanostructured RuO2–Co3O4@RuCo-EO with low Ru loading as a high-efficiency electrochemical oxygen evolution catalyst

Hydrogen Evolution Reaction - From Single Crystal to Single Atom Catalysts

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Nanostructured RuO₂–Co₃O₄@RuCo-EO with low Ru loading as a high-efficiency electrochemical oxygen evolution catalyst