In Situ Chemical Lithiation Transforms Diamond‐Like Carbon into an Ultrastrong Ion Conductor for Dendrite‐Free Lithium‐Metal Anodes

Li, Zhongzhong; Peng, Manqi; Zhou, Xiaolong; Shin, Kyungsoo; Tunmee, Sarayut; Zhang, Xiaoming; Xie, Chengde; Saitoh, Hidetoshi; Zheng, Yongping; Zhou, Zhiming; Tang, Yongbing

doi:10.1002/adma.202100793

Cited by 101 publications

(52 citation statements)

References 106 publications

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“…Recent researches indicated that in situ lithiation or prelithiation is another approach to improve the lithiophilicity and Li-ion conductivity of carbon materials. [42,43] This is actually consistent with our observation that after the first Li deposition/striping cycle inside aCNTs-600, the following cycles were significantly accelerated and the nanotube appeared superlithiophilic (see Video S3). As for the aCNTs (especially carbonized at 1000 °C) failed to encapsulate Li in the initial cycle, the aslithiated shells can also gain improved lithiophilicity, which could result in the encapsulation of Li in the following cycles in some cases (see Figure S35; such pre-lithiation may need a few cycles).…”

Section: Resultssupporting

confidence: 90%

Mechanistic Probing of Encapsulation and Confined Growth of Lithium Crystals in Carbonaceous Nanotubes

et al. 2021

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Encapsulation of lithium in the confined spaces within individual nanocapsules is intriguing and highly desirable for developing high‐performance Li metal anodes. This work aims for a mechanistic understanding of Li encapsulation and its confined growth kinetics inside 1D enclosed spaces. To achieve this, amorphous carbon nanotubes are employed as a model host using in situ transmission electron microscopy. The carbon shells have dual roles, providing geometric/mechanical constraints and electron/ion transport channels, which profoundly alter the Li growth patterns. Li growth/dissolution takes place via atom addition/removal at the free surfaces through Li+ diffusion along the shells in the electric field direction, resulting in the formation of unusual Li structures, such as poly‐crystalline nanowires and free‐standing 2D ultrathin (1–2 nm) Li membranes. Such confined front‐growth processes are dominated by Li {110} or {200} growing faces, distinct from the root growth of single‐crystal Li dendrites outside the nanotubes. Controlled experiments show that high lithiophilicity/permeability, enabled by sufficient nitrogen/oxygen doping or pre‐lithiation, is critical for the stable encapsulation of lithium inside carbonaceous nanocapsules. First‐principles‐based calculations reveal that N/O doping can reduce the diffusion barrier for Li+ penetration, and facilitate Li filling driven by energy minimization associated with the formation of low‐energy Li/C interfaces.

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Section: Resultssupporting

confidence: 90%

Mechanistic Probing of Encapsulation and Confined Growth of Lithium Crystals in Carbonaceous Nanotubes

et al. 2021

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“…S10†), the LiFePO 4 |PVDF–DBDPO/PP|Li cell demonstrates nonetheless an especially excellent performance with the specific capacity (113 mA h g −1 initially) and cycling stability (capacity retention of 100% after 1000 cycles) overwhelmingly superior to those of the LiFePO 4 |PP|Li cell (initial capacity of 98 mA h g −1 with the retention of 64.2%). Therefore, even when compared with the separators which are positively reported in the literature, 20,22,38,41,42,44,53,61–63 the LiFePO 4 /Li cell with the PVDF–DBDPO/PP separator still exhibits considerable competitive advantages (Fig. 7d), in not only the highly stable long-term cycling performance, but also the real demand of the lower-content liquid electrolyte (10 μL cm −2 ) for higher cell safety.…”

Section: Resultsmentioning

confidence: 83%

“…6–8 In this context, on the one hand, lots of efforts for safe LMBs commonly focus on exploring fire-prevention systems by introducing a fire retardant into electrolytes, 9,10 modifying separators with inorganic particles, 11,12 designing thermoresponsive switch membranes and so on. 13–15 On the other hand, the studies aspiring to achieve long cycling properties pay close attention to fresh strategies of electrolyte/electrode interface engineering for dendrite-free lithium anodes, such as in situ formation of an artificial SEI film, 16–18 construction of three-dimensional lithium matrices, 19 preparation of high-strength composite separators as mechanical barriers, 20,21 and interfacial redistribution of ions across the separators or at the lithium metal surface. 22–24 Both categories of these methods provide diversified perspectives for the progress of high-performance LMBs, while most of them only achieve high fire resistance or good lithium dendrite inhibition alone.…”

Section: Introductionmentioning

confidence: 99%

Sandwich-like solid composite electrolytes employed as bifunctional separators for safe lithium metal batteries with excellent cycling performance

Zhang

Shi

et al. 2022

J. Mater. Chem. A

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“…The parasitic reaction products were also visually negligible, as confirmed by detailed chemical analyses below. Although the suppression of the lithium dendrite by nano-porous separator have been reported 16 , 22 – 26 , inhibition the continuously occurred parasitic reaction between Li 0 and liquid electrolyte was firstly studied in this work.…”

Section: Resultsmentioning

confidence: 99%

Suppressing electrolyte-lithium metal reactivity via Li+-desolvation in uniform nano-porous separator

et al. 2022

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Lithium reactivity with electrolytes leads to their continuous consumption and dendrite growth, which constitute major obstacles to harnessing the tremendous energy of lithium-metal anode in a reversible manner. Considerable attention has been focused on inhibiting dendrite via interface and electrolyte engineering, while admitting electrolyte-lithium metal reactivity as a thermodynamic inevitability. Here, we report the effective suppression of such reactivity through a nano-porous separator. Calculation assisted by diversified characterizations reveals that the separator partially desolvates Li+ in confinement created by its uniform nanopores, and deactivates solvents for electrochemical reduction before Li0-deposition occurs. The consequence of such deactivation is realizing dendrite-free lithium-metal electrode, which even retaining its metallic lustre after long-term cycling in both Li-symmetric cell and high-voltage Li-metal battery with LiNi0.6Mn0.2Co0.2O2 as cathode. The discovery that a nano-structured separator alters both bulk and interfacial behaviors of electrolytes points us toward a new direction to harness lithium-metal as the most promising anode.

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In Situ Chemical Lithiation Transforms Diamond‐Like Carbon into an Ultrastrong Ion Conductor for Dendrite‐Free Lithium‐Metal Anodes

Cited by 101 publications

References 106 publications

Mechanistic Probing of Encapsulation and Confined Growth of Lithium Crystals in Carbonaceous Nanotubes

Mechanistic Probing of Encapsulation and Confined Growth of Lithium Crystals in Carbonaceous Nanotubes

Sandwich-like solid composite electrolytes employed as bifunctional separators for safe lithium metal batteries with excellent cycling performance

Suppressing electrolyte-lithium metal reactivity via Li+-desolvation in uniform nano-porous separator

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