Fast Charge‐Transfer Rates in Li‐CO<sub>2</sub> Batteries with a Coupled Cation‐Electron Transfer Process

Jaradat, Ahmad; Ncube, Musawenkosi K.; Papailias, Ilias; Rai, Nikhil; Kumar, Khagesh; Koverga, Volodymyr; Nemade, Roshan Y.; Zhang, Chengji; Shan, Nannan; Shahbazi, Hessam; Namaeighasemi, Arash; Seraji, Pardis; Namvar, Shahriar; Berry, Vikas; Cabana, Jordi; Subramanian, Arunkumar; Ngo, Anh T.; Curtiss, Larry A.; Salehi‐Khojin, Amin

doi:10.1002/aenm.202303467

Cited by 5 publications

(1 citation statement)

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“…AZIBs suffer from undesirable practical capacity or unsatisfactory cycle life due to a number of factors, including dendritic formation on the zinc anode, cathode material dissolution, and a sluggish transfer of bivalent Zn 2+ ions within host frameworks. 25–31 Recent research findings indicate that the application of aqueous electrolytes characterized by moderate acidity or neutrality can substantially improve the stability of the zinc anode. 32–35 By utilizing advanced cathode materials, AZIBs' cycle life and discharge capacity could be significantly increased, thereby broadening their application scope.…”

Section: Introductionmentioning

confidence: 99%

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Chahartagh,

Aghdam,

Namvar

et al. 2024

J. Mater. Chem. A

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Section: Introductionmentioning

confidence: 99%

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Chahartagh,

Aghdam,

Namvar

et al. 2024

J. Mater. Chem. A

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Unravelling the Capacity Degradation Mechanism of Thick Electrodes in Lithium‐Carbon Dioxide Batteries via Visualization and Quantitative Techniques

Zhang,

Xiao,

Yan

et al. 2024

Adv Funct Materials

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Lithium‐carbon dioxide batteries (LCBs) require a thick cathode electrode to fulfill their theoretical energy density and high areal capacity (mAh cm−2). However, understanding the design of thick porous electrodes in LCBs is challenging because of the complexity of coupled multispecies transport. Herein, a link is established between the microscopic behaviors of thick electrodes and macroscopic electrochemical performance through a spatio‐temporal resolution technique, filling the gap in knowledge on the degradation mechanism of thick electrodes. Surprisingly, the worst utilization site with the least product deposition is in the central part of the electrode rather than the traditionally presumed separator face. The secondary structure and reaction pathway of solid products exhibit a clear tendency toward spatial growth (on the electrode surface or in the interior). Combined with quantitative modeling, a critical current density shifting the dominance is found from CO2 to Li+ ions, thereby reversing the gradient of the product distribution. Finally, a hotspot map of failure mechanisms with different operating protocols is provided, serving as a guideline for the future design of thick electrodes. This work breaks the knowledge of multi‐field coupling within porous thick electrodes and can be extended to advanced Na (Li)‐CO2 (O2) battery design.

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Approaching Splendid Catalysts for Li–CO₂ Battery from the Theory to Practical Designing: A Review

Pan,

Ma,

Wang

et al. 2024

Advanced Materials

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Lithium carbon dioxide (Li–CO2) batteries, noted for their high discharge voltage of approximately 2.8 V and substantial theoretical specific energy of 1876 Wh kg−1, represent a promising avenue for new energy sources and CO2 emission reduction. However, the practical application of these batteries faces significant hurdles, particularly at high current densities and over extended cycle lives, due to their complex reaction mechanisms and slow kinetics. This paper delves into the recent advancements in cathode catalysts for Li–CO2 batteries, with a specific focus on the designing philosophy from composition, geometry, and homogeneity of the catalysts to the proper test conditions and real‐world application. It surveys the possible catalytic mechanisms, giving readers a brief introduction of how the energy is stored and released as well as the critical exploration of the relationship between material properties and performances. Specifically, optimization and standardization of test conditions for Li–CO2 battery research is highlighted to enhance data comparability, which is also critical to facilitate the practical application of Li–CO2 batteries. This review aims to bring up inspiration from previous work to advance the design of more effective and sustainable cathode catalysts, tailored to meet the practical demands of Li–CO2 batteries.

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Fast Charge‐Transfer Rates in Li‐CO₂ Batteries with a Coupled Cation‐Electron Transfer Process

Cited by 5 publications

References 43 publications

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Unravelling the Capacity Degradation Mechanism of Thick Electrodes in Lithium‐Carbon Dioxide Batteries via Visualization and Quantitative Techniques

Approaching Splendid Catalysts for Li–CO₂ Battery from the Theory to Practical Designing: A Review

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Fast Charge‐Transfer Rates in Li‐CO2 Batteries with a Coupled Cation‐Electron Transfer Process

Cited by 5 publications

References 43 publications

Enhancing the performance and cyclability of MoS2 cathodes with interspace layer engineering using polypyrrole

Enhancing the performance and cyclability of MoS2 cathodes with interspace layer engineering using polypyrrole

Unravelling the Capacity Degradation Mechanism of Thick Electrodes in Lithium‐Carbon Dioxide Batteries via Visualization and Quantitative Techniques

Approaching Splendid Catalysts for Li–CO2 Battery from the Theory to Practical Designing: A Review

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Product

Resources

About

Fast Charge‐Transfer Rates in Li‐CO₂ Batteries with a Coupled Cation‐Electron Transfer Process

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Enhancing the performance and cyclability of MoS₂ cathodes with interspace layer engineering using polypyrrole

Approaching Splendid Catalysts for Li–CO₂ Battery from the Theory to Practical Designing: A Review