Spinels: Controlled Preparation, Oxygen Reduction/Evolution Reaction Application, and Beyond

Zhao, Qing; Yan, Zhenhua; Chen, Chengcheng; Chen, Jun

doi:10.1021/acs.chemrev.7b00051

Cited by 1,334 publications

(796 citation statements)

References 781 publications

(1,829 reference statements)

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“…[79] Oxygen vacancy can be considered for the fabrication of hollowed oxides, because it can greatly enhance the electrical conductivity, expose more of the catalytic active site, accelerate the formation process of metaloxygen intermediates and thus effectively promote its oxygenrelated catalytic activity. [79] Oxygen vacancy can be considered for the fabrication of hollowed oxides, because it can greatly enhance the electrical conductivity, expose more of the catalytic active site, accelerate the formation process of metaloxygen intermediates and thus effectively promote its oxygenrelated catalytic activity.…”

Section: Discussionmentioning

confidence: 99%

Hollow‐Structured Metal Oxides as Oxygen‐Related Catalysts

et al. 2018

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high overpotential and sluggish kinetics. Generally, Pt, IrO 2 , and RuO 2 noble metal catalysts have improved kinetics. But, the high cost and unsatisfactory long-term durability of noble-metal-based catalysts are the main limitations for large-scale commercial applications. Supplying flexible electronic structures, transition metal oxides are the optimal oxygen-related catalysts in which the adsorbents binding to metal cations (M) are neither too strong nor too weak. [9] With overall understanding of crystal structure for common transition metal oxides, it has been demonstrated that [MO 6 ] octahedral configuration effectively accelerates the charge transfer process during a redox reaction. [10] In the octahedral field, the transition metal 3d orbit will be split into e g and t 2g . The e g orbital directed toward an O 2 molecule overlaps the O-2p δ orbital more strongly than the overlap between the t 2g and O-2p π orbitals. It thereof determines the energy gained by both the adsorption/desorption of oxygen on transition metal ions. Furthermore, the hollow structure promotes their reaction kinetics and durability. [11,12] Here, we will focus on the hollow structures (spinels, perovskites, and rutiles) and their oxygenrelated catalysis properties. And general design strategies and precise fabrication of hollow-structured transition metal oxides for oxygen-related catalysis will be summarized. To simplify, the hollow structure discussed here is a system with independent inner voids and can be monodisperse. Advantage and Synthesis of Hollow Structures Importance of Hollow Structures in Oxygen-Related CatalysisA large surface area is critical for hollow structure in oxygenrelated catalysis. It can significantly increase the active sites and reduce the mass density of an energy conversion device. In some special systems, the consumption of co-catalysts (especially noble metal) could also be saved. [13] Meanwhile, large void size is another key feature for hollow structure. It will mitigate the effects of volume change, provide structural stability and enhance the metal-air battery cyclic performance. The interconnected channels will promote the mass transfer performance and enhance the rate capability. [14] In addition, the encapsulation ability of hollow structure can avoid catalyst poisoning and increase chemical and thermal stabilities. [15] With precise control of the geometric parameter (length, diameter, and shell thickness), a shortened charge transfer path is Metal oxide hollow structures with large surface area, low density, and high loading capacity have received great attention for energy-related applications. Acting as oxygen-related catalysts, hollow-structured transition metal oxides offer low overpotential, fast reaction rate, and excellent stability. Herein, recent progress in the oxygen-related catalysis (e.g., oxygen evolution reaction (OER), oxygen reduction reaction (ORR), and metal-air batteries) of hollow-structured transition metal oxides is discussed. Through a comprehensive outline of hollo...

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Section: Discussionmentioning

confidence: 99%

Hollow‐Structured Metal Oxides as Oxygen‐Related Catalysts

et al. 2018

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“…As an extend, the rotating ring-disk electrode (RRDE) technique, in which the coaxial ring electrode could detect the products generated from the disk electrode, can distinguish whether the ORR processes via a two-electron way to generate H 2 O 2 or a four-electron pathway to generate OH À [30,31] by the following two equations: As an extend, the rotating ring-disk electrode (RRDE) technique, in which the coaxial ring electrode could detect the products generated from the disk electrode, can distinguish whether the ORR processes via a two-electron way to generate H 2 O 2 or a four-electron pathway to generate OH À [30,31] by the following two equations:…”

Section: Oxygen Redox Reactions and Kineticsmentioning

confidence: 99%

Nanocarbon‐Based Electrocatalysts for Rechargeable Aqueous Li/Zn‐Air Batteries

Wang

Chen

et al. 2018

ChemElectroChem

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Zn-air batteries have become the most attractive energy storage devices because of their extremely high theoretical energy density, which enables electric vehicles to drive long range. However, current achievements still suffer from poor cycle life, low practical energy density, low round-trip efficiency, and high manufacturing costs. One of the key challenges is the sluggish kinetics of oxygen electrochemistry during discharge and charge cycles. Thus, significant breakthroughs in design and synthesis of efficient electrocatalysts for the oxygen redox reaction are highly demanded. Nanocarbons, especially heteroatoms doped nanocarbons, are potential oxygen reduction reaction (ORR) catalysts due to the reasonable balance between catalytic activity, durability, and cost. Importantly, by introduction of transition metal nanoparticles, spinel oxides, layered-double hydroxides, perovskite oxides, and other metal oxides, the constructed nanocarbon-based materials could deliver promising bifunctional ORR and oxygen evolution reaction (OER) catalytic properties, which could be employed as air-cathode materials to improve energy storage performances, even to get commercialized. Here, an overview of the recent progress of nanocarbon-based electrocatalysts as air-cathode materials for rechargeable aqueous Li/Zn-air batteries is provided, aiming to highlight the benefits and issues of nanocarbon-based electrocatalysts as well as to outline the most promising results and applications so far.[a] Prof.

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“…Platinum is among the best catalysts for these electrochemical reactions [3]. However, due to its high cost, efforts have been made to develop metal oxide catalysts that can combine improved electrochemical activity with low cost [4]. Moreover, calcium-cobaltites (such as Ca 3 Co 4 O 9 , hereafter called C349) have been widely investigated for energy-related applications [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Electrochemical assessment of Ca3Co4O9 nanofibres obtained by Solution Blow Spinning

et al. 2018

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Ca 3 Co 4 O 9 (C349) nanofibres were obtained by Solution Blow Spinning (SBS) and evaluated as electrocatalysts for Oxygen Reduction and Oxygen Evolution Reactions (ORR and OER). Calcined nanofibres were characterised in terms of structural, morphological and electrochemical features.Results showed that catalytic activity of C349 nanofibres for ORR/OER is in line with literature data for carbon-related materials. The areal capacitance is much better than that of TiO 2 nanotubes.

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Spinels: Controlled Preparation, Oxygen Reduction/Evolution Reaction Application, and Beyond

Cited by 1,334 publications

References 781 publications

Hollow‐Structured Metal Oxides as Oxygen‐Related Catalysts

Hollow‐Structured Metal Oxides as Oxygen‐Related Catalysts

Nanocarbon‐Based Electrocatalysts for Rechargeable Aqueous Li/Zn‐Air Batteries

Electrochemical assessment of Ca3Co4O9 nanofibres obtained by Solution Blow Spinning

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