Unraveling the Catalytic Mechanism of Co3O4 for the Oxygen Evolution Reaction in a Li–O2 Battery

Zhu, Jinzhen; Ren, Xiaodong; Li, Jianjun; Zhang, Wenqing; Zhang, Wen

doi:10.1021/cs5014442

Cited by 148 publications

(140 citation statements)

References 73 publications

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“…[169,170] The high active catalyst should have an appropriate O adsorption strength close to those of well-established Pt and Pd catalysts. Other kinds of factors which can correlate with the performances, such as the catalyst size, [171,172] the crystal facet, [173,174] and the conductivity are reported. [175] Among these efforts, Zhu…”

Section: Correlation Between Electrocatalyst Property and Li-o 2 Battmentioning

confidence: 99%

Recent Progress in Electrocatalyst for Li‐O₂ Batteries

Zhou

Zhang

2017

Advanced Energy Materials

240

153

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In the Li‐O2 field, the electrocatalyst plays an important role in accelerating the sluggish electrochemical reactions, thus improving the performances of Li‐O2 battery. In this field, numerous researches regarding the incorporation of electrocatalyst have been published. With the aim to provide an easy as well as timely access for readers to follow the latest development in the catalyst area, the progress regarding the recent development on the application and research of electrocatalyst for Li‐O2 batteries is reviewed in a comprehensive and systematic manner. The application of various kinds of electrocatalyst including solid catalyst and soluble catalyst is first summarized. Then, relevant research including the catalyst design and the correlation between the catalyst property and the Li‐O2 battery performance is discussed. Finally, insights on how to fabricate an effective electrocatalyst are provided, which are expected to provide guidance for further catalyst design.

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Section: Correlation Between Electrocatalyst Property and Li-o 2 Battmentioning

confidence: 99%

Recent Progress in Electrocatalyst for Li‐O₂ Batteries

Zhou

Zhang

2017

Advanced Energy Materials

240

153

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“…Furthermore, they took surface acidity (defined as the energy change of catalysts with charge transfer) as a descriptor of charge transfer to study the electrocatalytic activity in the charging process [77,80,81]. They elucidated that the O-rich Co 3 O 4 (111) surface with a relatively low surface energy, promoting charge transfer from the Li 2 O 2 particles to the underlying surface, has a high catalytic activity to reduce overpotential and the O 2 evolution barrier [80]. Furthermore, as shown in Fig.…”

Section: Charge Transfermentioning

confidence: 99%

Adsorption-energy-based activity descriptors for electrocatalysts in energy storage applications

Wang

Qiu

Song

et al. 2017

National Science Review

Self Cite

156

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Energy storage technologies, such as fuel cells, ammonia production and lithium-air batteries, are important strategies for addressing the global challenge of energy crisis and environmental pollution. Taking overpotential as a direct criterion, we illustrate in theory and experiment that the adsorption energies of charged species such as Li + +e − and H + +e − are a central parameter to describe catalytic activities related to electricity-in/electricity-out efficiencies. The essence of catalytic activity is revealed to relate with electronic coupling between catalysts and charged species. Based on adsorption energy, some activity descriptors such as d-band center, e g -electron number and charge-transfer capacity are further defined by electronic properties of catalysts that directly affect interaction between catalysts and charged species. The present review is helpful for understanding the catalytic mechanisms of these electrocatalytic reactions and developing accurate catalytic descriptors, which can be employed to screen high-activity catalysts in future high-throughput calculations and experiments.

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“…To examine the catalytic effect, Zhu et al carried out firstprinciples studies on the Co 3 O 4 surfaces and suggested that the Co 3 O 4 surface with Lewis acid sites is capable of reducing charge voltages due to facilitated electron transfer from Li 2 O 2 to the catalytic surface and a reduced O 2 desorption barrier. 141 Using a carbon-free, oxide-only cathode, moreover, Lee and his co-workers have provided clear evidence that Co 3 O 4 and other spinel-type transition metal oxides have the ability to catalyse O 2 reduction and Li 2 O 2 decomposition in an ether-based electrolyte. 142,143 Given that Li 2 O 2 should be stored within the cathode, three-dimensional (3D) architectures of the cathode would play a significant role in determining the electrochemical performance of non-aqueous Li-air batteries.…”

Section: View Article Onlinementioning

confidence: 99%

Porous nanoarchitectures of spinel-type transition metal oxides for electrochemical energy storage systems

Park

Kim

et al. 2015

Phys. Chem. Chem. Phys.

147

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. (2015). Porous nanoarchitectures of spinel-type transition metal oxides for electrochemical energy storage systems. Physical Chemistry Chemical Physics, 17 (46), 30963-30977. Porous nanoarchitectures of spinel-type transition metal oxides for electrochemical energy storage systems AbstractTransition metal oxides possessing two kinds of metals (denoted as AxB3-xO4, which is generally defined as a spinel structure; A, B = Co, Ni, Zn, Mn, Fe, etc.), with stoichiometric or even non-stoichiometric compositions, have recently attracted great interest in electrochemical energy storage systems (ESSs). The spinel-type transition metal oxides exhibit outstanding electrochemical activity and stability, and thus, they can play a key role in realising cost-effective and environmentally friendly ESSs. Moreover, porous nanoarchitectures can offer a large number of electrochemically active sites and, at the same time, facilitate transport of charge carriers (electrons and ions) during energy storage reactions. In the design of spinel-type transition metal oxides for energy storage applications, therefore, nanostructural engineering is one of the most essential approaches to achieving high electrochemical performance in ESSs. In this perspective, we introduce spinel-type transition metal oxides with various transition metals and present recent research advances in material design of spinel-type transition metal oxides with tunable architectures (shape, porosity, and size) and compositions on the micro-and nano-scale. Furthermore, their technological applications as electrode materials for next-generation ESSs, including metal-air batteries, lithium-ion batteries, and supercapacitors, are discussed. The spinel-type transition metal oxides exhibit outstanding electrochemical activity and stability, and thus, they can play a key role in realising cost-effective and environmentally friendly ESSs. Moreover, porous nanoarchitectures can offer a large number of electrochemically active sites and, at the same time, facilitate transport of charge carriers (electrons and ions) during energy storage reactions. In the design of spinel-type transition metal oxides for energy storage applications, therefore, nanostructural engineering is one of the most essential approaches to achieving high electrochemical performance in ESSs. In this perspective, we introduce spinel-type transition metal oxides with various transition metals and present recent research advances in material design of spinel-type transition metal oxides with tunable architectures (shape, porosity, and size) and compositions on the micro-and nano-scale.Furthermore, their technological applications as electrode materials for next-generation ESSs, including metal-air batteries, lithium-ion batteries, and supercapacitors, are discussed.

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Unraveling the Catalytic Mechanism of Co₃O₄ for the Oxygen Evolution Reaction in a Li–O₂ Battery

Cited by 148 publications

References 73 publications

Recent Progress in Electrocatalyst for Li‐O₂ Batteries

Recent Progress in Electrocatalyst for Li‐O₂ Batteries

Adsorption-energy-based activity descriptors for electrocatalysts in energy storage applications

Porous nanoarchitectures of spinel-type transition metal oxides for electrochemical energy storage systems

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Unraveling the Catalytic Mechanism of Co3O4 for the Oxygen Evolution Reaction in a Li–O2 Battery

Cited by 148 publications

References 73 publications

Recent Progress in Electrocatalyst for Li‐O2 Batteries

Recent Progress in Electrocatalyst for Li‐O2 Batteries

Adsorption-energy-based activity descriptors for electrocatalysts in energy storage applications

Porous nanoarchitectures of spinel-type transition metal oxides for electrochemical energy storage systems

Contact Info

Product

Resources

About

Unraveling the Catalytic Mechanism of Co₃O₄ for the Oxygen Evolution Reaction in a Li–O₂ Battery

Recent Progress in Electrocatalyst for Li‐O₂ Batteries

Recent Progress in Electrocatalyst for Li‐O₂ Batteries