Rationalizing the Effect of Oxygen Vacancy on Oxygen Electrocatalysis in Li–O<sub>2</sub> Battery

Li, Jiabao; Shu, Chaozhu; Liu, Chunhai; Chen, Xianfei; Hu, Anjun; Long, Jianping

doi:10.1002/smll.202001812

Cited by 89 publications

(74 citation statements)

References 46 publications

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“…The vacancy defects in materials can induce more exposed active sites for guest ions and intermediate species and thus effectively facilitate ion diffusion and charge transfer through regulating the electronic structure. [ 164–166 ] As a kind of typical defects, oxygen vacancies (V O ) in S hosts were proven to efficiently anchor LiPSs and highly facilitate the S redox reaction. [ 167 ] An example is that Ba 0.5 Sr 0.5 Co 0.8 Fe 0.2 O 3– x perovskite nanoparticles (PrNPs) as catalysts can immobilize LiPSs and induce the Li 2 S deposition in Li–S battery.…”

Section: Optimization Strategies Of Redox Reactionmentioning

confidence: 99%

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Zhou

Lei

et al. 2020

Advanced Energy Materials

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119

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The lithium–sulfur battery is regarded as one of the promising energy‐storage devices beyond lithium‐ion battery due to its overwhelming energy density. The aprotic Li–S electrochemistry is hampered by issues arising from the complex solid–liquid–solid conversion process. Recently, tremendous efforts have been made to optimize the electrochemical reaction in Li–S batteries through rationally designing compositions and structures of cathodes. However, a deep and comprehensive understanding of the actual mechanisms of Li–S batteries and their impact on the performance is still insufficient. The vigorous development of various electrochemical analysis and in situ techniques establish a bridge between the microstructure of components and the macroscopic electrochemical performance, thus providing more scientific guidance for the optimal design of Li–S batteries. In this review, based on insights into the mechanism of aprotic Li–S electrochemistry with the aid of in situ characterization and electrochemical methods, the advanced innovations in optimizing Li–S batteries are systematically summarized, including the materials design, cathode configurations optimization, and electrolyte engineering, with the aim to gain a comprehensive understanding of cathodic redox processes and thus achieve high‐performance Li–S batteries. The current status and possible future directions of the field are accordingly outlined.

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Section: Optimization Strategies Of Redox Reactionmentioning

confidence: 99%

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Zhou

Lei

et al. 2020

Advanced Energy Materials

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119

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“…[147] 2) Doped ions of different sizes or generation of certain vacancy defects can change crystal cells structure, expand lattice channels, thus enhance ions diffusion coefficient. [148] 3) Doped ions can hinder grain growth, resulting in smaller average particle size than pure. [149] In previous reports, doping and vacancy has been studied in Nb-based materials.…”

Section: Lattice Optimizationmentioning

confidence: 99%

“…[149] Vacancies can significantly change the oxide electronic structure or the adsorption intermediate stability, thereby greatly enhance the electrochemical activity of oxide surface. [148] Meanwhile, the vacancy structure will greatly affect material properties, such as electronic structure, conductivity, and ion/electron diffusion rate. In fact, the electronic properties adjusted by vacancies can effectively promote charge transfer and redox reaction kinetics.…”

Section: Vacancy Modificationmentioning

confidence: 99%

Optimization Design and Application of Niobium‐Based Materials in Electrochemical Energy Storage

Lian

Yang

Wang

et al. 2020

Adv Energy and Sustain Res

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In various energy storage devices, the development and research of electrode materials has always been a key factor. Nb‐based materials are one choice of energy storage materials because of the good ion‐diffusion channels and high theoretical capacity. More importantly, their advantages, such as safe potential range, high structural stability, and highly reversible redox reaction with small strain, are conducive to efficient, safe, and stable energy storage development. Based on aforementioned superiority, much of the research is to further optimize performance of Nb‐based materials by unique nano‐morphology design, lattice regulation, and functional additives composition, showing good electrochemical performance in many kinds of devices. This review mainly introduces the classification of Nb‐based materials used for energy storage, their application in different battery systems, and common optimization methods. Accordingly, the deficiencies and prospects of Nb‐based materials are also discussed in detail.

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“…Meanwhile, the Lewis basic surface formed by high oxygen vacancy concentration leads to the unfavorable electron transfer from the discharged products to the low‐valence metal ions and hindering the decomposition of Li 2 O 2 , thereby aggravating the OER performance (Figure 7c). [ 193 ] Although cationic vacancies can also greatly affect the properties of metal compounds, large formation energy limits their application in the field of Li–O 2 battery. Metal atom doping can also be used to enhance the activity of catalysts.…”

Section: Cathodementioning

confidence: 99%

Section: Cathodementioning

confidence: 99%

Challenges and Strategy on Parasitic Reaction for High‐Performance Nonaqueous Lithium–Oxygen Batteries

Zhang

Ding

et al. 2020

Advanced Energy Materials

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is restricted to their inferior energy densities (≈250 Wh kg −1) due to intercalation chemistry. Consequently, "beyond Li-ion batteries" such as lithium-sulfur batteries and metal-air batteries, which have fundamental discrepant energy storage mechanism, have been attracted worldwide attention recently. [4,5] Of all the candidates, rechargeable lithium-oxygen battery (LOB) is considered to be one of the most fascinating next-generation batteries with extremely high theoretical energy density (≈3500 Wh kg −1). [6,7] The low-cost and environmental positive active material oxygen originates from air, endowing LOBs more attractive to satisfy the soaring demand of large-scale energy storage system. Generally, there are four architecture systems of LOBs determined by different electrolyte: aqueous, nonaqueous, hybrid, and all-solid-state. [8-11] In 1996, Abraham and Jiang first reported the rechargeable lithium-oxygen battery consisted of Li metal anode, solid polymer electrolyte membrane, and composite carbon cathode. [12] After ten years, nonaqueous LOBs actually caught worldwide attention due to the outstanding capacity and reversibility. [6] A typical nonaqueous lithium-oxygen battery comprises a metallic Li anode, organic electrolyte containing Li salt, a separator, and a porous gas diffusion cathode loading with catalysts (Figure 1). [13] Generally, the electrochemical reactions of nonaqueous lithium-oxygen battery can be described as following equations [14-16] Overall reaction E 2Li O Li O 2.96 V vs Li/Li 2 2 2 () + ↔°= + (1) Cathodic process (oxygen reduction reaction (ORR))

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Rationalizing the Effect of Oxygen Vacancy on Oxygen Electrocatalysis in Li–O₂ Battery

Cited by 89 publications

References 46 publications

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Optimization Design and Application of Niobium‐Based Materials in Electrochemical Energy Storage

Challenges and Strategy on Parasitic Reaction for High‐Performance Nonaqueous Lithium–Oxygen Batteries

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Rationalizing the Effect of Oxygen Vacancy on Oxygen Electrocatalysis in Li–O2 Battery

Cited by 89 publications

References 46 publications

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Optimizing Redox Reactions in Aprotic Lithium–Sulfur Batteries

Optimization Design and Application of Niobium‐Based Materials in Electrochemical Energy Storage

Challenges and Strategy on Parasitic Reaction for High‐Performance Nonaqueous Lithium–Oxygen Batteries

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Rationalizing the Effect of Oxygen Vacancy on Oxygen Electrocatalysis in Li–O₂ Battery