Silicene Flowers: A Dual Stabilized Silicon Building Block for High-Performance Lithium Battery Anodes

Zhang, Xinghao; Qiu, Xuwen; Kong, Debin; Zhou, Lu; Li, Zihao; Li, Xianglong; Zhi, Linjie

doi:10.1021/acsnano.7b03942

Cited by 135 publications

(107 citation statements)

References 58 publications

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“…To date, various 2D anode materials like titanium oxides, transition metal oxides, metal phosphides/sulfides/nitrides, have been extensively applied for LIBs. Among these 2D anode materials, 2D silicon have received intense attention as one of the most promising high‐capacity electrodes for the next‐generation LIBs due to its ultrahigh theoretical lithium storage capacity, faster Li diffusion rates, and relatively low discharge potential, as well as lower diffusion energy barrier (0.23 eV) of lithium ions . Despite these impressive benefits in 2D Si anodes, there remains a crucial challenge to realize its large‐scale preparation using low‐cost method.…”

Section: Introductionmentioning

confidence: 99%

Scalable 2D Mesoporous Silicon Nanosheets for High‐Performance Lithium‐Ion Battery Anode

Song

Chen

et al. 2018

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Constructing unique mesoporous 2D Si nanostructures to shorten the lithium-ion diffusion pathway, facilitate interfacial charge transfer, and enlarge the electrode-electrolyte interface offers exciting opportunities in future high-performance lithium-ion batteries. However, simultaneous realization of 2D and mesoporous structures for Si material is quite difficult due to its non-van der Waals structure. Here, the coexistence of both mesoporous and 2D ultrathin nanosheets in the Si anodes and considerably high surface area (381.6 m g ) are successfully achieved by a scalable and cost-efficient method. After being encapsulated with the homogeneous carbon layer, the Si/C nanocomposite anodes achieve outstanding reversible capacity, high cycle stability, and excellent rate capability. In particular, the reversible capacity reaches 1072.2 mA h g at 4 A g even after 500 cycles. The obvious enhancements can be attributed to the synergistic effect between the unique 2D mesoporous nanostructure and carbon capsulation. Furthermore, full-cell evaluations indicate that the unique Si/C nanostructures have a great potential in the next-generation lithium-ion battery. These findings not only greatly improve the electrochemical performances of Si anode, but also shine some light on designing the unique nanomaterials for various energy devices.

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Section: Introductionmentioning

confidence: 99%

Scalable 2D Mesoporous Silicon Nanosheets for High‐Performance Lithium‐Ion Battery Anode

Song

Chen

et al. 2018

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“…Unless otherwise specified, the capacity values reported were calculated on the basis of the total weight of the tested electrodes. It can be observed that the mSi@OG@RGO shows similar cyclic voltammetry (CV) peaks (Figure a and Figure S6, Supporting Information) and galvanostatic voltage profiles (Figure b) to those of other silicon anodes . Figure c displays the rate performance of the mSi@OG@RGO and the mSi@RGO control sample, demonstrating high rate capability of the mSi@OG@RGO.…”

mentioning

confidence: 78%

“…To address this electrode formulation failure and advance the use of silicon as the LIB anode material, various nanostructured silicon building blocks (e.g., nanoparticles, nanowires, nanotubes, and nanosheets) have been engaged, considering that structural fracture can be avoided, and electrical disconnection can be alleviated when decreasing the material feature size to the nanoscale . In particular, a wide range of materials design concepts have been further developed to construct void‐involved silicon/carbon nanostructures such as point‐to‐point contacted yolk–shell and line‐to‐line contacted wire‐in‐tube Si–C nanohybrids, so as to minimize destruction of the electrode architecture by the volume change of individual material particles as well as render a stable SEI on the surface of individual material particles thereby restraining the degradation of electron/lithium ion transport paths from/to silicon.…”

mentioning

confidence: 99%

“…In particular, a wide range of materials design concepts have been further developed to construct void‐involved silicon/carbon nanostructures such as point‐to‐point contacted yolk–shell and line‐to‐line contacted wire‐in‐tube Si–C nanohybrids, so as to minimize destruction of the electrode architecture by the volume change of individual material particles as well as render a stable SEI on the surface of individual material particles thereby restraining the degradation of electron/lithium ion transport paths from/to silicon. Although being successful in extending the cycling life of silicon, the use of silicon nanostructures and their nanohybrids has inevitably incurred new fundamental challenges, some of which include increased side reactions and lowered coulombic efficiency due to higher surface area, low tap density and compromised volumetric capacity (and, therefore, energy density), weakened electrical properties and generally reduced rate capability because of excess interparticle resistances (and also intrinsically limited Si–C contact modes in the case of popular void‐involved Si–C nanohybrids), and also poor scalability and unacceptable cost due to complex synthesis processes.…”

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confidence: 99%

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Scallop‐Inspired Shell Engineering of Microparticles for Stable and High Volumetric Capacity Battery Anodes

Zhang

Guo

et al. 2018

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Building stable and efficient electron and ion transport pathways are critically important for energy storage electrode materials and systems. Herein, a scallop-inspired shell engineering strategy is proposed and demonstrated to confine high volume change silicon microparticles toward the construction of stable and high volumetric capacity binder-free lithium battery anodes. As for each silicon microparticle, the methodology involves an inner sealed but adaptable overlapped graphene shell, and an outer open hollow shell consisting of interconnected reduced graphene oxide, mimicking the scallop structure. The inner closed shell enables simultaneous stabilization of the interfaces of silicon with both carbon and electrolyte, substantially facilitates efficient and rapid transport of both electrons and lithium ions from/to silicon, the outer open hollow shell creates stable and robust transport paths of both electrons and lithium ions throughout the electrode without any sophisticated additives. The resultant self-supported electrode has achieved stable cycling with rapidly increased coulombic efficiency in the early stage, superior rate capability, and remarkably high volumetric capacity upon a facile pressing process. The rational design and engineering of graphene shells of the silicon microparticles developed can provide guidance for the development of a wide range of other high capacity but large volume change electrochemically active materials.

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“…Silica fume and magnesium (Mg) powder as starting materials were mixed together and then heated to a high temperature to synthesize silicene (Figure 4). 73 As‐prepared silicene flowers were further employed as lithium battery anodes, which exhibited extraordinary electrochemical performance. The feasibility of this technique endows great potential for the preparation of silicene.…”

Section: Synthesis and Structures Of 2d Group‐iv Materialsmentioning

confidence: 99%

Two‐dimensional materials of group‐IVA boosting the development of energy storage and conversion

Guo

Chen

2020

Carbon Energy

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Graphene, an emerging fabric of carbon atoms, has manifested its versatility in all kinds of fields encompassing electronics, optoelectronics, thermoelectrics, taking advantage of its excellent mechanical strength, exceptional electronic and thermal conductivities, high surface specific area, and so forth. The prosperity of graphene never seen before has led the attention to silicene, siloxene, germanene, stanene, and plumbene due to their promising applications in the quantum spin Hall effect, topological insulator, batteries, capacitors, catalysis, and topological superconductivity. Herein, we review the existing production methods, numerous applications of two‐dimensional group‐IVA materials, and critically discuss the challenges of these materials, providing potential implications to the exploration of uncharted material systems.

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Silicene Flowers: A Dual Stabilized Silicon Building Block for High-Performance Lithium Battery Anodes

Cited by 135 publications

References 58 publications

Scalable 2D Mesoporous Silicon Nanosheets for High‐Performance Lithium‐Ion Battery Anode

Scalable 2D Mesoporous Silicon Nanosheets for High‐Performance Lithium‐Ion Battery Anode

Scallop‐Inspired Shell Engineering of Microparticles for Stable and High Volumetric Capacity Battery Anodes

Two‐dimensional materials of group‐IVA boosting the development of energy storage and conversion

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