Enhanced Cyclability of Lithium Metal Anodes Enabled by Anti-aggregation of Lithiophilic Seeds

Sun, Jia; Cheng, Yong; Zhang, Hehe; Yan, Xiaolin; Sun, Zhefei; Ye, Weibin; Li, Wangqin; Zhang, Mingyue; Gao, Haowen; Han, Jiajia; Peng, Dong‐Liang; Yang, Yong; Wang, Ming‐Sheng

doi:10.1021/acs.nanolett.2c01736

Cited by 28 publications

(19 citation statements)

References 41 publications

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“…More impressively, even if the current density increases to 10 mA cm −2 , the WDC-GDAg battery can still cycle over 200 h without short circuits, which is far beyond the cycling life of the WDC and Li foil (Figure 3e; Figure S16, Supporting Information). This remarkable cycling stability and rate performance endow the gradient-distributed 3D structures with great competitiveness among the everreported lithium metal modulation strategies in the latest literature [17,31,50,51,[67][68][69][70][71][72][73][74] (Figure S17, Supporting Information).…”

Section: Resultsmentioning

confidence: 93%

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Zhu

Liu

Fang

et al. 2022

Advanced Energy Materials

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Li deposition behavior and cycling stability for Li-O 2 battery by boosting Li + transport ability. Yan et al. [33] constructed an organic/ inorganic dual-layered SEI layer to protect the Li metal anode from the corrosion of electrolytes and achieve uniform Li deposition/stripping. Xu et al. [34] proposed a stable tissue-directed/reinforced bifunctional separator to suppress the growth of lithium dendrites.However, the infinite volume variation of Li metal anode during discharge/charge processes could also cause the cracking of SEI layer and the formation of dead Li, resulting in low CE and poor cycling stability. [35][36][37][38] Designing 3D current collectors as the Li anode hosts such as 3D copper foam, [39][40][41][42] 3D carbon, [43][44][45] 3D nickel foam [46,47] have been found to be effective in relieving these challenges by providing the deposition space and diminishing the volume variation of Li metal [37,[48][49][50][51] It's worth mentioning that low tortuosity 3D current collectors, such as vertically aligned graphene oxide, [52] carbonized wood [53] and vertically aligned TiO 2 nanotubes, [54,55] have been proved to be beneficial for the fast and stable Li + transport. Unfortunately, these intricate 3D structures would result in inhomogeneous distribution of local current density and thus generate "hot spots" for Li dendrite formation on the top of 3D electrode at high current density, which significantly increases the risk of safety issues. [52][53][54][56][57][58][59] Therefore, it is highly crucial to spatially control the Li deposition far from the interface between electrode and separator in the 3D current collectors. In light of that, laminated structures with lithiophilic layers at the bottom were prepared to control the Li metal deposition at the bottom of electrode, which exhibited improved stability during the cycling processes. [10,[60][61][62] Since the lithiophilic layers would be gradually embedded in the deposited lithium during the lithium deposition process, the spatial controllability of lithium deposition for the laminated design is not ideal enough. In this regard, gradient-distributed lithiophilic sites in 3D scaffolds could be more favorable, yet synthetically challenging to achieve such unique structures.Inspired by the substances transpiration process in trees, we herein successfully achieve gradient-distributed lithiophilic sites including Ag, ZnO, and Au, in low-tortuosity 3D wood derived carbon (WDC) frameworks by a simple capillary-induced gradient deposition. Due to the merits of excellent spatial

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Section: Resultsmentioning

confidence: 93%

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Zhu

Liu

Fang

et al. 2022

Advanced Energy Materials

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“…Meanwhile, the spherical morphology of SiO x /C@C is well maintained after cycling, without dissolution or aggregation problems such as lithiophilic Au or Ag "seeds" (Figure S11, Supporting Information). [22,42] Reviewing the whole lithiation/Li plating process of yolk-shell SiO x /C@C as shown in Video S1, Supporting Information; Figure 3a, it is observed that the Li deposition always begins at the interface, that is to say, the contact point between SiO x /C core and N,S co-doped C shell (indicated by the red circle in Figure 3c).…”

Section: Resultsmentioning

confidence: 99%

“…[ 17–21 ] The aggregation or dissolution of these materials during cycling will lead to insufficient regulation effects and inaccessible voids for Li deposition. Besides, some oxide‐based lithiophilic “sites” (TiO 2 , SiO x /C) have also been employed to regulate the Li deposition, demonstrating better structural stability than the above‐mentioned metallic lithiophilic “sites.” [ 22,23 ] Doping the carbon materials with foreign atoms can also improve the lithiophilicity; [ 24–26 ] however, as Li is deposited only on the surface of the hollow carbon without entering it, [ 27 ] Li dendrites will form as well when the deposited Li increases (Scheme 1b). Due to the insufficiently utilized void space, the Li storage capacities are usually low (<3 mAh cm −2 ) before the dendrite is formed.…”

Section: Introductionmentioning

confidence: 99%

Sequential and Dendrite‐Free Li Plating on Cu Foil Enabled by an Ultrathin Yolk–Shell SiO_x/C@C Layer

Wang

Zhang

et al. 2023

Advanced Energy Materials

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Lithium metal anodes are considered to be the ultimate candidate for Li‐based batteries; however, their development is hindered by uncontrollable Li deposition. Porous hosts and Cu foil with lithiophilic decorations have proven effective in Li dendrite suppression. However, the failure of lithiophilic decorations during cycling causes inaccessible encapsulated voids for Li‐deposition. And the almost electrochemically inert feature of host/decoration materials will result in undesirable loss in gravimetric capacity. Herein, an ultrathin layer of stable and electroactive yolk‐shell SiOx/C@C with designed differences in lithiophilicity is constructed on Cu foil. The more lithiophilic SiOx/C core over doped C shell induces sequential Li plating from intra‐particle voids to inter‐particle spaces and then above the modification layer. Such a plating process is reversed during Li stripping. Even after considering the mass of SiOx/C@C modification layer, a high specific capacity of 2818 mAh g−1 can be achieved. The Li–SiOx/C@C–Cu anode demonstrates a decent cyclability over 500 h under strict conditions in symmetric cells. When paired with a LiFePO4 cathode (10.5 mg cm−2), the full cell with a N/P ratio of 2 manifests a high capacity retention of 91.3% over 350 cycles, demonstrating its practical application value in future lithium metal batteries.

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“…Carbon nanofibers (CNFs) usually have high specific surface area, rich pore structure, excellent chemical stability, and high electrical conductivity and, as artificial protective layers, have been shown to effectively reduce local current density and regulate lithium deposition. − For example, the carbonized silk nanofiber (SCNF) films were used as double interlayers of lithium-sulfur batteries, which could inhibit the growth of lithium dendrites on the LMA side and block dissolved polysulfides on the sulfur cathode side to reduce their corrosion to lithium metal (Figure a) . In addition, the doping of nanoparticles or nanosheets into carbon-based materials as heterogeneous seeds can effectively guide lithium deposition and achieve spatial control of lithium nucleation, which is a common tactic to enhance the lithiophilicity of carbon-based protective layers. − As shown in Figure b, Wei and co-workers manufactured ordered carbon nanofiber films (MnS@CNC/CNFs) doped with MnS nanoparticles and cellulose nanocrystalline (CNC) by microfluidic spinning techniques and carbonization processes . The MnS nanoparticles in the fiber film underwent similar alloying reaction with Li + , and the polar functional group (−OH) in the CNC had a strong adsorption effect on Li + , which could guide Li + to be uniformly plated on the electrode surface, thus effectively inhibiting the formation of dendritic lithium (Figure c).…”

Section: Nanofibrous Materials For Artificial Protective Layersmentioning

confidence: 99%

Advances in Nanofibrous Materials for Stable Lithium-Metal Anodes

Zhao

Yan

et al. 2022

ACS Nano

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Lithium metal is regarded as the most potential anode material for improving the energy density of batteries due to its high specific capacity and low electrode potential. However, the practical application of lithium-metal anodes (LMAs) still faces severe challenges such as uncontrollable dendrites growth and large volume expansion. The development of functional nanomaterials has brought opportunities for the revival of LMAs. Among them, nanofibrous materials show great application potential for LMAs protection due to their distinct functional and structural features. Here, the latest research progress in nanofibrous materials for LMAs is systematically outlined. First, the problems existing in the practical application of LMAs are analyzed. Then, prospective strategies and recent research progress toward stable LMAs based on nanofibrous materials are summarized from the aspects of artificial protective layers, three-dimensional frameworks, separators, and solid-state electrolytes. Finally, the future development of nanofibrous materials for the protection of lithium-metal batteries is summarized and prospected. This review establishes a close connection between nanofibrous materials and LMA modification and provides insight for the development of high-safety lithium-metal batteries.

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Enhanced Cyclability of Lithium Metal Anodes Enabled by Anti-aggregation of Lithiophilic Seeds

Cited by 28 publications

References 41 publications

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Sequential and Dendrite‐Free Li Plating on Cu Foil Enabled by an Ultrathin Yolk–Shell SiO_x/C@C Layer

Advances in Nanofibrous Materials for Stable Lithium-Metal Anodes

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Enhanced Cyclability of Lithium Metal Anodes Enabled by Anti-aggregation of Lithiophilic Seeds

Cited by 28 publications

References 41 publications

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Spatially Distributed Lithiophilic Gradient in Low‐Tortuosity 3D Hosts via Capillary Action for High‐Performance Li Metal Anodes

Sequential and Dendrite‐Free Li Plating on Cu Foil Enabled by an Ultrathin Yolk–Shell SiOx/C@C Layer

Advances in Nanofibrous Materials for Stable Lithium-Metal Anodes

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Sequential and Dendrite‐Free Li Plating on Cu Foil Enabled by an Ultrathin Yolk–Shell SiO_x/C@C Layer