An electron-deficient carbon current collector for anode-free Li-metal batteries

Kwon, Hyeokjin; Lee, Ju‐Hyuk; Roh, Youngil; Baek, Jaewon; Shin, Dongjae; Yoon, Jong Keon; Ha, Hoe Jin; Kim, Je Young; Kim, Hee‐Tak

doi:10.1038/s41467-021-25848-1

Cited by 114 publications

(44 citation statements)

References 46 publications

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“…The intensity ratio of these defects to sp 2 -hybridized carbon is 0.35 (calculated on the basis of the integral areas of the peaks), indicative of a high defect population. The peak centred at 284.1 eV represents the carbon vacancies at the lattice sites, and the peak at 285.2 eV can be assigned to nonconjugated carbon that mostly include hydrogenated carbon ( 30 , 31 ). Vacancies in graphene have been proved able to induce the formation of Li-intercalated states with a high lithium-to-carbon ratio such as Li 3 C 8 ( 32 ), compared to the common LiC 6 .…”

Section: Resultsmentioning

confidence: 99%

Rationalized design of hyperbranched trans-scale graphene arrays for enduring high-energy lithium metal batteries

Fang

Han

et al. 2022

Sci. Adv.

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Lithium (Li) metal anode have shown exceptional potential for high-energy batteries. However, practical cell-level energy density of Li metal batteries is usually limited by the low areal capacity (<3 mAh cm −2 ) because of the accelerated degradation of high–areal capacity Li metal anodes upon cycling. Here, we report the design of hyperbranched vertical arrays of defective graphene for enduring deep Li cycling at practical levels of areal capacity (>6 mAh cm −2 ). Such atomic-to-macroscopic trans-scale design is rationalized by quantifying the degradation dynamics of Li metal anodes. High-energy Li metal cells are prototyped under realistic conditions with high cathode capacity (>4 mAh cm −2 ), low negative-to-positive electrode capacity ratio (1:1), and low electrolyte-to-capacity ratio (5 g Ah −1 ), which shed light on a promising move toward practical Li metal batteries.

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Section: Resultsmentioning

confidence: 99%

Rationalized design of hyperbranched trans-scale graphene arrays for enduring high-energy lithium metal batteries

Fang

Han

et al. 2022

Sci. Adv.

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“…The produced multi-channels provided sufficient space for volume changes of lithium, while Ag nanoparticles ensured homogeneous nucleation and deposition. Kwon et al (2021 ) synthesized an atomically defective carbon current collector with multivacancy defects using the surface-oxidized carbon fiber paper to induce homogeneous SEI formation and uniform lithium growth. Polymers usually contain a number of polar groups, such as hydroxyl, nitro, and carboxyl, which possess excellent lithiophilicity.…”

Section: Engineering Strategies For Anode Current Collectormentioning

confidence: 99%

“…The capacity retention of the anode-free cell was improved from 13.3% to ∼73.3% after 50 cycles. The atomically defective carbon current collector invented by Kwon et al (2021 ) successfully elevated the capacity retention of AFLMB to 90% over 50 cycles under lean electrolyte conditions. Lin et al (2021 ) applied an epitaxial induced plating current collector (E-Cu) with a GaInSn liquid metal (LM) layer to facilitate Li + diffusion and initiate epitaxial growth of lithium, resulting in increased capacity retention from 66% to 84% in 50 cycles of an anode-free NCM811||E-Cu pouch cell with a remarkable energy density of 420 Wh/kg.…”

Section: Application Of Current Collector Engineeringmentioning

confidence: 99%

Rational Engineering of Anode Current Collector for Dendrite-Free Lithium Deposition: Strategy, Application, and Perspective

Jia

Liu

et al. 2022

Front. Chem.

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Lithium metal anodes have attracted extensive attention due to their high theoretical capacity and low redox potential. However, low Coulombic efficiency, serious parasitic reaction, large volume change, and dendrite growth during cycling have hindered their practical application. The engineering of an anode current collector provides important advances to solve these problems, eliminate excess lithium usage, and substantially increase the energy density. In this review, we summarize the engineering strategies of an anode current collector with emphasis on different methods and applications in lithium metal-based systems. Finally, the perspectives and challenges of current collector engineering for lithium metal anode are discussed.

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“…This pre-lithiation behavior enhances their affinity with the deposited lithium. Various carbon materials (few-layer graphite or multilayer graphene Deng et al, 2018;Liu W. et al, 2019;Ren et al, 2019), carbon nanotubes (Wang Y. et al, 2017;Guo et al, 2018;Guo et al, 2019), carbon fiber (Lin et al, 2019;Liao et al, 2020;Kwon et al, 2021), etc.) have been proved effective for mitigating the Li dendrite growth due to their porous structure and/or affinity with lithium.…”

Section: Electrochemically Reactive Substratesmentioning

confidence: 99%

“…have been proved effective for mitigating the Li dendrite growth due to their porous structure and/or affinity with lithium. Kwon et al (Kwon et al, 2021) reported an atomically defective carbon current collector where multi-vacancy defects induce homogeneous SEI formation, uniform lithium nucleation and growth to obtain a dense lithium morphology. Zuo et al (Zuo et al, 2017) developed graphitized carbon fiber electrode to enhance the Li storage capacity (Figure 1A).…”

Section: Electrochemically Reactive Substratesmentioning

confidence: 99%

Controlled Lithium Deposition

Zhang

Yang

et al. 2022

Front. Energy Res.

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Lithium metal is a promising anode material for its low redox potential and high theoretical specific capacity. However, the commercial application of the lithium metal anode is hindered with safety concerns arising from the uncontrolled growth of the lithium dendrites and significant volume variation during the lithium plating and stripping processes. Modification to the current collector is effective in tailoring the morphology of the deposited lithium and improving the cycling performance of the lithium metal batteries This review summarizes at first the global research advances in the structural design and the selection of the current collectors and their textures. It then presents some of our efforts in realizing controlled lithium deposition by designing current collectors in three aspects, lithium deposition induced by the micro-to-nano structures, lithiophilic alloys and iron carbides. Finally, conclusions and prospects are made for the further research of the current collectors.

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An electron-deficient carbon current collector for anode-free Li-metal batteries

Cited by 114 publications

References 46 publications

Rationalized design of hyperbranched trans-scale graphene arrays for enduring high-energy lithium metal batteries

Rationalized design of hyperbranched trans-scale graphene arrays for enduring high-energy lithium metal batteries

Rational Engineering of Anode Current Collector for Dendrite-Free Lithium Deposition: Strategy, Application, and Perspective

Controlled Lithium Deposition

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