Constraining Si Particles within Graphene Foam Monolith: Interfacial Modification for High‐Performance Li<sup>+</sup> Storage and Flexible Integrated Configuration

Ma, Yanwei; Younesi, Reza; Pan, Ruijun; Liu, Chenjuan; Zhu, Jiefang; Wei, Bingqing; Edström, Kristina

doi:10.1002/adfm.201602324

Cited by 82 publications

(53 citation statements)

References 49 publications

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“…However, the commercial graphite anode exhibits a low theoretical capacity of only 372 mA h g −1 . To address this issue, numerous investigations have been made to explore and design new anode materials with high capacity and long cycle life, such as Si, Sn, transitional metal oxides and sulfides . Among many classes of alternative anode materials, metal phosphides seem to be a new potential to replace graphite due to their low polarization, minor electrode volume expansion, and high gravimetric capacity based on either intercalation or conversion reactions .…”

Section: Introductionmentioning

confidence: 99%

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Dai

Sun

et al. 2017

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Metal phosphides are a new class of potential high-capacity anodes for lithium ion batteries, but their short cycle life is the critical problem to hinder its practical application. A unique ball-cactus-like microsphere of carbon coated NiP /Ni Sn with deep-rooted carbon nanotubes (Ni-Sn-P@C-CNT) is demonstrated in this work to solve this problem. Bimetal-organic-frameworks (BMOFs, Ni-Sn-BTC, BTC refers to 1,3,5-benzenetricarboxylic acid) are formed by a two-step uniform microwave-assisted irradiation approach and used as the precursor to grow Ni-Sn@C-CNT, Ni-Sn-P@C-CNT, yolk-shell Ni-Sn@C, and Ni-Sn-P@C. The uniform carbon overlayer is formed by the decomposition of organic ligands from MOFs and small CNTs are deeply rooted in Ni-Sn-P@C microsphere due to the in situ catalysis effect of Ni-Sn. Among these potential anode materials, the Ni-Sn-P@C-CNT is found to be a promising anode with best electrochemical properties. It exhibits a large reversible capacity of 704 mA h g after 200 cycles at 100 mA g and excellent high-rate cycling performance (a stable capacity of 504 mA h g retained after 800 cycles at 1 A g ). These good electrochemical properties are mainly ascribed to the unique 3D mesoporous structure design along with dual active components showing synergistic electrochemical activity within different voltage windows.

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Section: Introductionmentioning

confidence: 99%

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Dai

Sun

et al. 2017

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“…Raman spectroscopy (Figure d) of p‐SiNSs@C‐2 exhibits a disorder‐induced D band and a graphitic G band. The calculated I D / I G of silicon composite is ≈0.55, demonstrating that the carbon layer has a high degree of graphitization and a high electronic conductivity . In addition, the two peaks located at 512 and 940 cm −1 are the characteristic peaks of nanosilicon .…”

Section: Resultsmentioning

confidence: 90%

Catalytic Growth of Graphitic Carbon‐Coated Silicon as High‐Performance Anodes for Lithium Storage

Shi

Nie

et al. 2019

Energy Tech

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Although silicon is considered as one of the most promising anode materials in next‐generation lithium‐ion batteries, large volumetric expansion during cycling hampers its practical application. The fabrication of silicon/carbon composites is an effective way to improve electrical conductivity and inhibit electroactive material delaminating from the current collector. Herein, a graphitic carbon‐coated porous silicon nanospheres (p‐SiNSs@C) composite is prepared through a chemical vapor deposition (CVD) technique by using the magnesiothermic reduction by‐product MgO as a template and catalyst. With the template of in situ generation of MgO, the p‐SiNSs@C material is obtained in a very short time. Due to the graphitic carbon shell and porous structure inside the silicon nanospheres, the obtained p‐SiNSs@C, with 8 min carbon growing time (p‐SiNSs@C‐2), deliver a high initial reversible capacity of 2220 mAh g−1 at 0.1 A g−1 and respectable rate capability. Furthermore, the p‐SiNSs@C‐2//LiCoO2 Li‐ion full cell displays a high energy density of ≈409 Wh kg−1 and good cycling performance. The high performance of the p‐SiNSs@C‐2 composite can be attributed to the synergistic effect of nanoscale‐sized Si, porous structure, and stable carbon shell.

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“…The Raman spectra of various rGO‐MoS 2 /NC composites were compared in Figure f. For all the composites, there exist two broad peaks at Raman shifts of 1371 and 1593 cm −1 , assignable to the in‐plane vibrations of SP 3 amorphous carbon (D band) and SP 2 graphic carbon (G band), respectively . Noted that the I D /I G value gradually increased from 0.81 to 1.01, indicating the reduced graphitization degree among the composites upon the heavier dosage of rGO component .…”

Section: Resultsmentioning

confidence: 99%

Integrated Thin Film Battery Design for Flexible Lithium Ion Storage: Optimizing the Compatibility of the Current Collector‐Free Electrodes

Zhao

Bai

et al. 2019

Adv Funct Materials

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The design of flexible full-cell configuration relies on the light-weight arrangement, structural robustness, compositional compatibility, and shape conformability of the coherent components. In this article, a general and scalable spin-coating approach is developed to integrate the flexible, current-collector-free cathode and anode in the thin film batteries with the layer-stacked configuration. The design of the ternary composite anode involves the reduced graphene oxide encapsulation of the MoS 2 /N-doped carbon microrods composite (rGO-MoS 2 / NC) via the facile hydrothermal-calcination process. In the similar structure design of the cathode, the ball-milled nanocrystalline mixture of LiMn 2 O 4 and LiVPO 4 F is wrapped within the GO interfacial protection layer. Furthermore, the slurries of electroactive materials with the predetermined areal capacity ratio of negative to positive electrodes (N/P ratio) are cast onto both sides of the nano-SiO 2 modified polyethylene (SiO 2 -MPE) separator via the facile spincoating process. The prototype full-cell configuration delivers a high reversible capacity, satisfactory capacity retention at the high rate, as well as good cyclability under different mechanical loadings. This integrated thin film battery model showcases its potential use in the flexible electronic devices.

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Constraining Si Particles within Graphene Foam Monolith: Interfacial Modification for High‐Performance Li⁺ Storage and Flexible Integrated Configuration

Cited by 82 publications

References 49 publications

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Catalytic Growth of Graphitic Carbon‐Coated Silicon as High‐Performance Anodes for Lithium Storage

Integrated Thin Film Battery Design for Flexible Lithium Ion Storage: Optimizing the Compatibility of the Current Collector‐Free Electrodes

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Constraining Si Particles within Graphene Foam Monolith: Interfacial Modification for High‐Performance Li+ Storage and Flexible Integrated Configuration

Cited by 82 publications

References 49 publications

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Bimetal-Organic-Framework Derivation of Ball-Cactus-Like Ni-Sn-P@C-CNT as Long-Cycle Anode for Lithium Ion Battery

Catalytic Growth of Graphitic Carbon‐Coated Silicon as High‐Performance Anodes for Lithium Storage

Integrated Thin Film Battery Design for Flexible Lithium Ion Storage: Optimizing the Compatibility of the Current Collector‐Free Electrodes

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Constraining Si Particles within Graphene Foam Monolith: Interfacial Modification for High‐Performance Li⁺ Storage and Flexible Integrated Configuration