Singlet oxygen generation as a major cause for parasitic reactions during cycling of aprotic lithium–oxygen batteries

Mahne, Nika; Schafzahl, Bettina; Leypold, Christian; Leypold, Mario; Grumm, Sandra; Leitgeb, Anita; Strohmeier, Gernot A.; Wilkening, Martin; Fontaine, Olivier; Kramer, Denis; Slugovc, Christian; Borisov, Sergey M.; Freunberger, Stefan

doi:10.1038/nenergy.2017.36

Cited by 375 publications

(531 citation statements)

References 54 publications

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“…[16] Thedifferent chemical stability between NaO 2 and KO 2 can be related to their thermodynamic properties. [24,25] Even though both NaO 2 and KO 2 have been identified as discharge products,o nly KO 2 is thermodynamically stable.H ence,t he spontaneous disproportionation route to peroxide is prohibited in K-O 2 cells,which distinguishes them from Na-O 2 cells. [13,14] Theincreased charge overpotential triggers parasitic reactions and dramatically decreased cell efficiency.…”

Section: Angewandte Chemiementioning

confidence: 99%

The Long‐Term Stability of KO₂ in K‐O₂ Batteries

et al. 2018

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The rechargeable K-O 2 battery is recognized as ap romising energy storage solution owingt oi ts large energy density,l ow overpotential, and high coulombic efficiency based on the single-electron redoxc hemistry of potassium superoxide.H owever,t he reactivity and long-term stability of potassium superoxide remains ambiguous in K-O 2 batteries. Parasitic reactions are explored and the use of ion chromatography to quantify trace amounts of side products is demonstrated. Both quantitative titrations and differential electrochemical mass spectrometry confirm the highly reversible single-electron transfer process,w ith 98 %c apacity attributed to the formation and decomposition of KO 2 .Incontrast to the Na-O 2 counterparts,r emarkable shelf-life is demonstrated for K-O 2 batteries owing to the thermodynamic and kinetic stability of KO 2 ,which prevents the spontaneous disproportionation to peroxide.T his work sheds light on the reversible electrochemical process of K + + e À + O 2 $KO 2 .

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Section: Angewandte Chemiementioning

confidence: 99%

The Long‐Term Stability of KO₂ in K‐O₂ Batteries

et al. 2018

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“…[9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] Several excellent reviews have been published to summarize recent developments and our current understanding of Li-O 2 batteries, especially with respect to the cathode electrocatalytic materials. [25][26][27][28][29][30][31][32][33][34][35] These reviews have comprehensively discussed the relationship between the structure of electrocatalytic materials and the electrochemical performance of Li-O 2 batteries.…”

Section: Publication Detailsmentioning

confidence: 99%

Review of Electrolytes in Nonaqueous Lithium–Oxygen Batteries

Guo

Luo

Chen

et al. 2018

Advanced Sustainable Systems

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Based on an inexhaustible and ubiquitous source of oxygen, the lithium-oxygen batteries are currently the subject of much scientific investigation because of their potential for extremely high energy density. The electrocatalytic materials for them have been extensively researched during the past decade. Even though they are a key component in the lithium-oxygen batteries, however, the study of electrolytes is still in its primary stage. Electrolytes have an important influence on the electrochemical performance of lithium-oxygen batteries, especially on their cycling stability and rate capacity. Therefore, it is important to select an ideal electrolyte with excellent stability against attack by reaction intermediates, along with excellent oxygen solubility and diffusivity. In this review, the physicochemical and electrochemical properties of organic electrolytes for lithium-oxygen batteries are discussed and compared. Furthermore, possible research directions are proposed for the development of an ideal electrolyte for enhanced electrochemical performance. Disciplines Engineering | Physical Sciences and Mathematics Publication DetailsGuo, H., Luo, W., Chen, J., Chou, S., Liu, H. & Wang, J. (2018 Figure 1. Unlike the intercalation mechanism of lithium-ion batteries or sodium-ion batteries, the Li-O 2 battery systems employ a dissolution/ deposition reaction with an air electrode that uses oxygen as the cathode electrode during the electrochemical processes. Research on the Li-O 2 battery is complicated by the need for exposure the air cathode to O 2 atmosphere.Many advances have been achieved, which include advances on cathode materials, electrolytes, anode materials, and redox mediators. [9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] Several excellent reviews have been published to summarize recent developments and our current understanding of Li-O 2 batteries, especially with respect to the cathode electrocatalytic materials. [25][26][27][28][29][30][31][32][33][34][35] These reviews have comprehensively discussed the relationship between the structure of electrocatalytic materials and the electrochemical performance of Li-O 2 batteries. There are, however, few reviews focused on the effects of different electrolytes on the electrochemical performance of the Li-O 2 batteries. [36][37][38] For the aqueous Li-O 2 batteries, LiOH is generated or oxidized at the cathode during discharge and charge processes because H 2 O and O 2 are involved in the reactions. In the case of the nonaqueous Li-O 2 batteries, there are two essential processes that determine their electrochemical performance: the oxygen reduction reaction (ORR) and the oxygen evolution reaction (OER). During the ORR process, the Li 2 O 2 is precipitated as the final discharge product on the air cathode, while during the OER process, Li 2 O 2 is then decomposed and the O 2 is regenerated. Therefore, there are huge differences between aqueous and nonaqueous Li-O 2 batteries. Since the nonaqueous Li-O 2 batteries have dominated ...

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“…The identification of active reaction intermediates is challenging due to their short lifetimes. In situ/operando characterization techniques allow in situ monitoring of Li 2 O 2 evolution, such as the local atomic structure transformation and the evolution of intermediates along with discharge and charge processes . For example, Peng et al conducted in situ surface‐enhanced Raman spectroscopy (SERS) measurements where the Li 2 O 2 ‐related peak intensity clearly increased with diminishing LiO 2 peak intensity during the charge process.…”

Section: Defects Formed During the Discharge/charge Processesmentioning

confidence: 99%

“…There are two widely adopted Li 2 O 2 growth models, the solution model and the surface model, that largely determine the discharge capacity and charge overpotential by controlling the structure and morphology of Li 2 O 2 . However, a series of parasitic reactions can occur during discharge and charge and lead to carbon‐based cathode decomposition and electrolyte decomposition to form irreversible carbonates, resulting in low coulombic efficiency and cyclability deterioration . These concomitant side reactions primarily arise from attacks of the active species (O 2 − , LiO 2 , and Li 2 O 2 ) .…”

Section: Introductionmentioning

confidence: 99%

“…Other charge transport pathways (e.g., grain boundaries and trapping sites) can also be created by introducing defects to achieve multichannel conduction . The presence of these defects can significantly enhance the conductivity of Li 2 O 2 and promote charge transport through Li 2 O 2 , thus increasing the cycling stability of Li–O 2 batteries . Employing other energy carriers such as LiOH and LiO 2 has been explored as an effective way to circumvent charge transport issues.…”

Section: Introductionmentioning

confidence: 99%

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Defect Chemistry in Discharge Products of Li–O₂ Batteries

et al. 2018

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Li–O2 batteries, possessing the highest theoretical specific energy density among all known Li‐ion‐based batteries, demonstrate great potential as energy storage devices for powering electric vehicles. However, their battery performance is significantly limited by the insulating nature of the discharge product Li2O2, which has a wide bandgap (4–5 eV), resulting in high charge overpotential. Defect engineering of the discharge product emerges as a very promising strategy to improve the electrical conductivity and hence reduce the charge overpotential. The aim of this review is to highlight recent advances and progress in understanding and controlling the defect chemistry of discharge products in Li–O2 batteries. First, the theoretical perspectives of defects in Li2O2 are reviewed, with particular emphasis on defect design and engineering strategies to significantly improve the charge transport properties of Li2O2. Then intermediate defects in Li2O2 formed during the discharge and charge processes and materials with induced defects, including Li2− x O2, doped Li2O2, Li2O2 with surface/grain boundaries, and amorphous Li2O2, which are tailored by engineered catalysts and electrolyte additives are discussed. Finally, other alternative energy carriers for new energy storage chemistry of Li–O2 batteries, such as lithium superoxide, lithium hydroxide, and lithium carbonate, will also be discussed.

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Singlet oxygen generation as a major cause for parasitic reactions during cycling of aprotic lithium–oxygen batteries

Cited by 375 publications

References 54 publications

The Long‐Term Stability of KO₂ in K‐O₂ Batteries

The Long‐Term Stability of KO₂ in K‐O₂ Batteries

Review of Electrolytes in Nonaqueous Lithium–Oxygen Batteries

Defect Chemistry in Discharge Products of Li–O₂ Batteries

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Singlet oxygen generation as a major cause for parasitic reactions during cycling of aprotic lithium–oxygen batteries

Cited by 375 publications

References 54 publications

The Long‐Term Stability of KO2 in K‐O2 Batteries

The Long‐Term Stability of KO2 in K‐O2 Batteries

Review of Electrolytes in Nonaqueous Lithium–Oxygen Batteries

Defect Chemistry in Discharge Products of Li–O2 Batteries

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Product

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The Long‐Term Stability of KO₂ in K‐O₂ Batteries

The Long‐Term Stability of KO₂ in K‐O₂ Batteries

Defect Chemistry in Discharge Products of Li–O₂ Batteries