Oxygen Evolution via the Bridging Inequivalent Dual-Site Reaction: First-Principles Study of a Quadruple-Perovskite Oxide Catalyst

Takamatsu, Akihiko; Yamada, Ikuya; Yagi, Shunsuke; Ikeno, Hidekazu

doi:10.1021/acs.jpcc.7b10748

Cited by 31 publications

(22 citation statements)

References 47 publications

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“…At present, noble metal–based materials for OER, such as ruthenium oxides, are still ranking the highest level. [ 16,17 ] Meanwhile, nonnoble metal compounds, for instance, transition metal oxides, [ 18–21 ] perovskite, [ 22,23 ] hydroxide, [ 24,25 ] nitrides, [ 26,27 ] borates, [ 28,29 ] and so on, have also captured extensive interests for preparing high‐efficient OER catalysts. Among them, the metal fluoride, mostly literature reported for supercapacitor, lithium ion battery, etc., [ 30–33 ] is rarely wielded in the field of water electrolysis, possibly due to the chemical/electrochemical instability of fluoride ions and the weak bond between the metal ions and fluoride ions.…”

Section: Introductionmentioning

confidence: 99%

Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Dong

et al. 2020

Adv Materials Inter

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limits the availability of new types of energy. [4] Accordingly, hydrogen has been considered as a promising energy carrier to storage renewable energy through electrocatalytic water splitting. Great progress has been achieved to improve the electrolytic efficiency of the hydrogen evolution reaction (HER) [5,6] and oxygen evolution reaction (OER). [7,8] For HER, many nonnoble metal compounds have replaced traditional noble metal catalysts and have been utilized with satisfying catalytic efficiency. [9][10][11][12] Concerning to the fourelectron OER process, its reaction rates determine the overall catalytic efficiency of the water electrolysis. [13][14][15] Therefore, it is of particular importance to develop OER catalysts with high activity and durability.At present, noble metal-based materials for OER, such as ruthenium oxides, are still ranking the highest level. [16,17] Meanwhile, nonnoble metal compounds, for instance, transition metal oxides, [18][19][20][21] perovskite, [22,23] hydroxide, [24,25] nitrides, [26,27] borates, [28,29] and so on, have also captured extensive interests for preparing high-efficient OER catalysts. Among them, the metal fluoride, mostly literature reported for supercapacitor, lithium ion battery, etc., [30][31][32][33] is rarely wielded in the field of water electrolysis, possibly due to the chemical/electrochemical instability of fluoride ions and the weak bond between the metal ions and fluoride ions. Actually, fluoride ions can be easily replaced by other anions during the testing process, which is beneficial to optimize the catalytic activity by anionic reconstruction. [34] Consequently, metal fluoride is one of the most promising candidates to enhance the OER activity. Cobalt-based compounds, high-efficient catalytic activity for OER, have been considered one of the most prospective nonnoble catalysts in alkaline conditions for their low cost, rich source, and excellent corrosion resistance. [35][36][37][38][39] In addition, atomic doping or substitution can further improve its electrocatalytic performance by introducing more defects and catalytic active sites. [40][41][42] Herein, we took Fe-doped CoF 2 as research object to explore its electrocatalytic performance and catalytic mechanism in water splitting. Pristine CoF 2 was fabricated through a facile two-step reaction of hydrothermal method and chemical vapor deposition fluorination process. Furthermore, Fe 3+ was introduced into the resultant by adding iron agent into the precursor solution. The obtained Fe-doped CoF 2 revealed better electrocatalytic performance compared to pristine CoF 2 in 1 m Electrocatalytic water splitting is one of the most promising green solutions for large-scale hydrogen production, which has developed rapidly in recent years. The slow reaction rate of oxygen evolution reaction (OER) has become the bottleneck to improve the electrocatalytic efficiency. Herein, Fe-doped CoF 2 nanowire arrays on 3D nickel foam are prepared by two steps of hydrothermal reaction and fluorination process. The increa...

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Section: Introductionmentioning

confidence: 99%

Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Dong

et al. 2020

Adv Materials Inter

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“…Song and co-workersd esigned ah eterogeneousc atalyst with dual-metal sites, consisting of single Ni and Fe atoms embedded into g-C 3 N 4 units (Scheme 17 and Figure 7). [178] They found that oxygen evolution occurredt hrough the bridg-ing-inequivalent dual-site reaction, and OER adsorbates formed as trong chemical bond to the coordination-unsaturated octahedral site and aw eak chemical bond to ac oordination-saturated tetrahedral site or asquare-planar site (Figure 8). These dual-metal-site catalysts may offer an ew route to synthesize efficient WOCs.…”

Section: Dual-metal-site Wocsmentioning

confidence: 99%

“…In addition, Ikeno and co-workers investigated the higherO ER activity of the quadruple perovskite oxide LaMn 7 O 12 than that of the simple perovskite LaMnO through DFT computations. [178] They found that oxygen evolution occurredt hrough the bridg-ing-inequivalent dual-site reaction, and OER adsorbates formed as trong chemical bond to the coordination-unsaturated octahedral site and aw eak chemical bond to ac oordination-saturated tetrahedral site or asquare-planar site (Figure 8).…”

Section: Dual-metal-site Wocsmentioning

confidence: 99%

Mono‐/Multinuclear Water Oxidation Catalysts

Zhang

Guan

2019

ChemSusChem

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Water splitting, in which water molecules can be transformed into hydrogen and oxygen, is an appealing energy conversion and transformation strategy to address the environmental and energy crisis. The oxygen evolution reaction (OER) is dynamically slow, which limits energy conversion efficiency during the water‐splitting process and requires high‐efficiency water oxidation catalysts (WOCs) to overcome the OER energy barrier. It is generally accepted that multinuclear WOCs possess superior OER performances, as demonstrated by the CaMn4O5 cluster in photosystem II (PSII), which can catalyze the OER efficiently with a very low overpotential. Inspired by the CaMn4O5 cluster in PSII, some multinuclear WOCs were synthesized that could catalyze water oxidation. In addition, some mononuclear molecular WOCs also show high water oxidation activity. However, it cannot be excluded that the high activity arises from the formation of dimeric species. Recently, some mononuclear heterogeneous WOCs showed a high water oxidation activity, which testified that mononuclear active sites with suitable coordination surroundings could also catalyze water oxidation efficiently. This Review focuses on recent progress in the development of mono‐/multinuclear homo‐ and heterogeneous catalysts for water oxidation. The active sites and possible catalytic mechanisms for water oxidation on the mono‐/multinuclear WOCs are provided.

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“…For instance, the strain of MO 6 octahedra in perovskite oxides varies the splitting of e g orbitals and impacts on the strength of metal–oxygen bonds to determine the oxygen evolution reaction (OER)/oxygen reduction reaction (ORR) activity . Also, some researchers found that distinct geometry coordination structure sites (distorted tetrahedral sites, or corner sharing of AO 4 and BO 5 sites) favorably adsorbed reaction intermediate species, which enhanced the activity of catalysts with those sites . Reports that elucidate the role of the local structure are limited to water oxidation or the ORR, the mechanisms of which have been extensively studied.…”

Section: Introductionmentioning

confidence: 99%

“…[20] Also, somer esearchersf ound that distinct geometry coordination structure sites (distorted tetrahedrals ites, or corner sharing of AO 4 and BO 5 sites) favorably adsorbed reactioni ntermediate species, whiche nhanced the activity of catalysts with those sites. [21,22] Reports that elucidate the role of the local structurea re limited to water oxidation or the ORR, the mechanisms of which have been extensively studied.…”

Section: Introductionmentioning

confidence: 99%

Structure–Activity Relationship of Iron Oxides for NO Reduction in the Presence of C₃H₆, CO, and O₂

Ueda

Ohyama

Sawabe

et al. 2019

Chemistry A European J

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Spinel‐type NiFe2O4 exhibited the highest NO reduction activity among base‐metal oxides under simulated exhaust of a gasoline‐powered vehicle. The structure–activity relationship of iron oxides has been investigated through both experimental and computational studies. Spinel iron oxide (γ‐Fe2O3) exhibited a much higher NO reduction activity than that of iron oxide with other structures (α‐Fe2O3 and LaFeO3). Operando IR measurements clarified that the spinel structure facilitated the reaction between NOx and adsorbed oxidized hydrocarbon or cyanide species. The high reactivity of the spinel structure was ascribed to the high adsorption energy of NO, as elucidated by DFT calculations. Furthermore, molecular orbital calculations demonstrated that the local coordination structure of the spinel iron oxide induced the involvement of not only σ but also π orbitals during NO adsorption on Fe atoms. This work clarified the origin of the structure‐dependent activity of metal oxides, with a focus on their local coordination structures.

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Oxygen Evolution via the Bridging Inequivalent Dual-Site Reaction: First-Principles Study of a Quadruple-Perovskite Oxide Catalyst

Cited by 31 publications

References 47 publications

Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Mono‐/Multinuclear Water Oxidation Catalysts

Structure–Activity Relationship of Iron Oxides for NO Reduction in the Presence of C₃H₆, CO, and O₂

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Oxygen Evolution via the Bridging Inequivalent Dual-Site Reaction: First-Principles Study of a Quadruple-Perovskite Oxide Catalyst

Cited by 31 publications

References 47 publications

Atomic Doping and Anion Reconstructed CoF2 Electrocatalyst for Oxygen Evolution Reaction

Atomic Doping and Anion Reconstructed CoF2 Electrocatalyst for Oxygen Evolution Reaction

Mono‐/Multinuclear Water Oxidation Catalysts

Structure–Activity Relationship of Iron Oxides for NO Reduction in the Presence of C3H6, CO, and O2

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Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Atomic Doping and Anion Reconstructed CoF₂ Electrocatalyst for Oxygen Evolution Reaction

Structure–Activity Relationship of Iron Oxides for NO Reduction in the Presence of C₃H₆, CO, and O₂