Elucidating the Relationship between Quality Control of the Coating Layer and Suppression of Gas Evolution in Li-Ion Batteries

Lee, Youbean; Park, Chanjoo; Park, Kwangjin

doi:10.1021/acs.chemmater.3c01998

Cited by 7 publications

(1 citation statement)

References 93 publications

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“…Meanwhile, CVC mode is employed to preserve electrochemical equilibrium in the overvoltage state, which occurs due to polarization of the electrodes in the CC mode. [37] The higher percentage of capacity generation in the CVC mode represents the increasing polarization. The CVC capacity and percentage of CVC capacity in total charge capacity are shown in Figure S6c and Figure 4e.…”

Section: Electrochemical Performancementioning

confidence: 99%

Understanding the Effects of Bi Modification on the Properties of Ni‐Rich Cathodes

Meng,

Hou,

Thanwisai

et al. 2024

Batteries & Supercaps

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With the skyrocketing market demands for energy storage, lithium ions batteries (LIB) with higher energy density are urgently needed. Cathodes play a critical role in determining the energy density of LIB, and the most popular one is Ni‐rich cathode due to its high capacity. However, due to the fast structural degradation, Ni‐rich cathode materials should be further modified to achieve higher stability. Herein, we introduce bismuth ions in LiNi0.83Co0.11Mn0.06O2 cathodes by adding Bi2O3 during sintering to optimize the specific capacity and cycle stability. By adding 0.1% mol Bi, the Li+ diffusion and structural stability are effectively optimized, leading to improved electrochemical performances. The modified sample delivers much higher specific capacity (222.9 mAhg‐1, 0.05C) than unmodified sample (204 mAhg‐1, 0.05C). Meanwhile, the specific capacity of optimized sample after 100 cycles at 0.33C is 27.75 mAhg‐1 higher than that of unmodified sample. Therefore, this work demonstrates that Bi doping can be regarded as a possible solution to optimizing the electrochemical performance of Ni‐rich cathodes.

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Section: Electrochemical Performancementioning

confidence: 99%

Understanding the Effects of Bi Modification on the Properties of Ni‐Rich Cathodes

Meng,

Hou,

Thanwisai

et al. 2024

Batteries & Supercaps

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Decoding Air‐Exposure Degradation Chemistry and Improving Strategy for Layered Sodium Transition Metal Oxide Cathodes

Li,

Tang,

et al. 2024

Advanced Energy Materials

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Developing suitable cathodes of sodium‐ion batteries (SIBs) with robust electrochemical performance and industrial application potential is crucial for the commercialization of large‐scale stationary energy storage systems. Layered sodium transition metal oxides, NaxTmO2 (Tm representing transition metal), possessing considerable specific capacity, high operational potential, facile synthesis, cost‐effectiveness, and environmentally friendly characteristics, stand out as viable cathode materials. Nevertheless, the prevailing challenge of air‐induced degradation in most NaxTmO2 significantly increases costs associated with production, storage, and transportation, coupled with a rapid decay in reversible capacity. This inherent obstacle inevitably impedes the advancement and commercial viability of SIBs. To address this challenge, it is essential to decode the chemistry of degradation caused by air exposure and develop protective strategies accordingly. In this review, a comprehensive and in‐depth understanding of the fundamental mechanisms associated with air‐induced degradation is provided. Additionally, the current state‐of‐the‐art effective protective strategies are explored and discuss the corresponding sustainability and scalability features. This review concludes with an outlook on present and future research directions concerning air‐stable cathode materials, offering potential avenues for upcoming investigations in advancing alkali metal layered oxides.

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Architecting Sturdy Si/Graphite Composite with Lubricative Graphene Nanoplatelets for High‐Density Electrodes

Park,

Choi,

Lee

et al. 2024

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Densification of the electrode by calendering is essential for achieving high‐energy density in lithium‐ion batteries. However, Si anode, which is regarded as the most promising high‐energy substituent of graphite, is vulnerable to the crack during calendering process due to its intrinsic brittleness. Herein, a distinct strategy to prevent the crack and pulverization of Si nanolayer‐embedded Graphite (Si/G) composite with graphene nanoplatelets (GNP) is proposed. The thickly coated GNP layer on Si/G by simple mechanofusion process imparts exceptional mechanical strength and lubricative characteristic to the Si/G composite, preventing the crack and pulverization of Si nanolayer against strong external force during calendering process. Accordingly, GNP coated Si/G (GNP‐Si/G) composite demonstrates excellent electrochemical performances including superior cycling stability (15.6% higher capacity retention than P‐Si/G after 300 cycles in the full‐cell) and rate capability under the industrial testing condition including high electrode density (>1.6 g cm−3) and high areal capacity (>3.5 mAh cm−2). The material design provides a critical insight for practical approach to resolve the fragile properties of Si/G composite during calendering process.

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Elucidating the Relationship between Quality Control of the Coating Layer and Suppression of Gas Evolution in Li-Ion Batteries

Cited by 7 publications

References 93 publications

Understanding the Effects of Bi Modification on the Properties of Ni‐Rich Cathodes

Understanding the Effects of Bi Modification on the Properties of Ni‐Rich Cathodes

Decoding Air‐Exposure Degradation Chemistry and Improving Strategy for Layered Sodium Transition Metal Oxide Cathodes

Architecting Sturdy Si/Graphite Composite with Lubricative Graphene Nanoplatelets for High‐Density Electrodes

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