Confined Transformation of Organometal‐Encapsulated MOFs into Spinel CoFe<sub>2</sub>O<sub>4</sub>/C Nanocubes for Low‐Temperature Catalytic Oxidation

Qin, Lei; Xu, Zhi‐Kang; Zheng, Yilian; Li, Chang; Mao, Jingwen; Zhang, Guoliang

doi:10.1002/adfm.201910257

Cited by 62 publications

(35 citation statements)

References 63 publications

(74 reference statements)

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“…The pyrolysis of MOFs with ordered calcination modulates various characteristics, such as conductivity and porosity, surface area, stability, and catalytic activity; hence, such derivatives are highly interesting for water splitting. [23][24][25][26][27][28][29][30] Based on these guidelines, diverse MOF-based/derived materials have been reported in the past five years. However, a comprehensive review summarizing MOF-based/derived materials with well-defined synthetic methods, chemical compositions, nanostructured morphologies, electrocatalytic activities, and reaction mechanisms is urgently needed to provide strong inspiration and direct future developments in engineering MOFbased/derived electrocatalysts for water splitting.…”

Section: Introductionmentioning

confidence: 99%

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: Introductionmentioning

confidence: 99%

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

et al. 2021

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“…The morphology control of catalyst provides a good opportunity to improve the catalytic properties and enhance its efficiency. [ 17,25–28 ] To confirm the tunable structures of catalysts, we initially focused on the morphological properties of Co x O y nanoarrays. Scanning electron microscope (SEM) images reveal that crystal shape and size of Co x O y nanoarrays are very sensitive toward reaction temperature.…”

Section: Resultsmentioning

confidence: 99%

Crystal Facet Induced Single‐Atom Pd/Co_xO_y on a Tunable Metal–Support Interface for Low Temperature Catalytic Oxidation

Zhang

Qin

et al. 2020

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Atomic dispersed metal sites in single‐atom catalysts are highly mobile and easily sintered to form large particles, which deteriorates the catalytic performance severely. Moreover, lack of criterion concerning the role of the metal–support interface prevents more efficient and wide application. Here, a general strategy is reported to synthesize stable single atom catalysts by crafting on a variety of cobalt‐based nanoarrays with precisely controlled architectures and compositions. The highly uniform, well‐aligned, and densely packed nanoarrays provide abundant oxygen vacancies (17.48%) for trapping Pd single atoms and lead to the creation of 3D configured catalysts, which exhibit very competitive activity toward low temperature CO oxidation (100% conversion at 90 °C) and prominent long‐term stability (continuous conversion at 60 °C for 118 h). Theoretical calculations show that O vacancies at high‐index {112} facet of CoxOy nanocrystallite are preferential sites for trapping single atoms, which guarantee strong interface adhesion of Pd species to cobalt‐based support and play a pivotal role in preventing the decrement of activity, even under moisture‐rich conditions (≈2% water vapor). The progress presents a promising opportunity for tailoring catalytic properties consistent with the specific demand on target process, beyond a facile design with a tunable metal–support interface.

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“…The observed enhanced catalytic activity of 2.0 wt% Pt/Co 2.73 Zr 0.27 O 4 is suggested to result from the formation of abundant oxygen vacancies and higher Co 2+ /Co total ratios. [ 37 ] Figure 6d presents the Arrhenius plots for toluene combustion over the Co 3 O 4 , Co 2.73 Zr 0.27 O 4 , 0.5 wt% Pt/Co 2.73 Zr 0.27 O 4 , 1.0 wt% Pt/Co 2.73 Zr 0.27 O 4 , and 2.0 wt% Pt/Co 2.73 Zr 0.27 O 4 samples at a weight hourly space velocity of 36 000 mL h −1 g −1 . Comparison of the apparent E a values shows Co 2.73 Zr 0.27 O 4 ( E a = 98.69 kJ mol −1 ) and 2.0 wt% Pt/Co 2.73 Zr 0.27 O 4 ( E a = 66.18 kJ mol −1 ) to have lower E a values compared with Co 3 O 4 , which further implies enhanced performance toward the catalytic oxidation of toluene.…”

Section: Resultsmentioning

confidence: 99%

“…The observed enhanced catalytic activity of 2.0 wt% Pt/Co 2.73 Zr 0.27 O 4 is suggested to result from the formation of abundant oxygen vacancies and higher Co 2+ /Co total ratios. [37] Figure 6d presents , which further implies enhanced performance toward the catalytic oxidation of toluene. [38,39] Furthermore, the comparison of the temperature at which 90% toluene is converted is presented in Figure 6c.…”

Section: Catalytic Performance and Kinetic Parametersmentioning

confidence: 96%

Nanocage‐Shaped Co₃₋_xZr_xO₄ Solid‐Solution Supports Loaded with Pt Nanoparticles as Effective Catalysts for the Enhancement of Toluene Oxidation

Wang

Chen

et al. 2020

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Nanocage‐shaped Co3−xZrxO4 solid‐solution supports and the corresponding platinum loaded nanocomposites, yPt/Co3−xZrxO4 (x =0.27, 0.50, 0.69; y = 0.5, 1.0, 2.0 wt.%), are successfully fabricated via a Cu2O nanocube hard template method and a glycol reduction method, respectively. The hollow nanocage structures obviously improve surface areas; moreover, the Zr doping forms the Co3−xZrxO4 solid‐solution supports, and the corresponding yPt/Co3−xZrxO4 catalysts promote the enhancement of catalytic performance. Catalytic activity toward toluene combustion is enhanced for the 2.0 wt% Pt/Co2.73Zr0.27O4 catalyst. The catalysts are characterized using multiple techniques. Pt nanoparticles are uniformly dispersed across the Co2.73Zr0.27O4 nanocage surface. The 2.0 wt% Pt/Co2.73Zr0.27O4 catalyst exhibits the highest catalytic activity among all the samples and demonstrates good stability, with 90% toluene conversion obtained at a temperature of 165 °C. The same catalyst accomplishes full toluene oxidation at 180 °C, at a weight hourly space velocity of 36 000 mL h−1 g−1. The apparent activation energy (Ea) over the yPt/Co2.73Zr0.27O4 samples are significantly lower than those over the Co3−xZrxO4 supports, with the 2.0 wt% Pt/Co2.73Zr0.27O4 catalyst exhibiting the lowest Ea value. These findings demonstrate the potential of the 2.0 wt% Pt/Co2.73Zr0.27O4 catalyst as a promising catalyst toward atmospheric toluene removal.

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Confined Transformation of Organometal‐Encapsulated MOFs into Spinel CoFe₂O₄/C Nanocubes for Low‐Temperature Catalytic Oxidation

Cited by 62 publications

References 63 publications

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Crystal Facet Induced Single‐Atom Pd/Co_xO_y on a Tunable Metal–Support Interface for Low Temperature Catalytic Oxidation

Nanocage‐Shaped Co₃₋_xZr_xO₄ Solid‐Solution Supports Loaded with Pt Nanoparticles as Effective Catalysts for the Enhancement of Toluene Oxidation

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Confined Transformation of Organometal‐Encapsulated MOFs into Spinel CoFe2O4/C Nanocubes for Low‐Temperature Catalytic Oxidation

Cited by 62 publications

References 63 publications

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Designing MOF Nanoarchitectures for Electrochemical Water Splitting

Crystal Facet Induced Single‐Atom Pd/CoxOy on a Tunable Metal–Support Interface for Low Temperature Catalytic Oxidation

Nanocage‐Shaped Co3−xZrxO4 Solid‐Solution Supports Loaded with Pt Nanoparticles as Effective Catalysts for the Enhancement of Toluene Oxidation

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Confined Transformation of Organometal‐Encapsulated MOFs into Spinel CoFe₂O₄/C Nanocubes for Low‐Temperature Catalytic Oxidation

Crystal Facet Induced Single‐Atom Pd/Co_xO_y on a Tunable Metal–Support Interface for Low Temperature Catalytic Oxidation

Nanocage‐Shaped Co₃₋_xZr_xO₄ Solid‐Solution Supports Loaded with Pt Nanoparticles as Effective Catalysts for the Enhancement of Toluene Oxidation