Tubular Graphene Nano-Scroll Coated Silicon for High Rate Performance Lithium-Ion Battery

Shi, Min; Nie, Ping; Fan, Zengjie; Fu, Ruirui; Fang, Shan; Dou, Hui; Zhang, Xiaogang

doi:10.3389/fenrg.2020.00002

Cited by 6 publications

(3 citation statements)

References 41 publications

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“…Figure 2A presents three typical peaks of C1s, N1s, and O1s without any impurities in three samples. The spectrum of C 1s exhibits that the primary characteristic peaks at 284.6, 285.9, and 289.1 eV denote the C-C, C-N, and O-C=O of CNs, MCNs, and BMCNs ( Figure 2B), respectively (Zheng et al, 2014;Chu et al, 2018;Shi et al, 2020). Four obvious peaks of N 1s at 398.4, 399.7, 400.6, and 402.4 eV are related to pyridinic N, pyrrolic N, graphitic N, and oxidized N in Figure 2C (Chen et al, 2016;Liu et al, 2017;Peng et al, 2019).…”

Section: Resultsmentioning

confidence: 99%

Polydopamine-Derived Carbon: What a Critical Role for Lithium Storage?

et al. 2020

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Polydopamine-derived carbon materials have attracted tremendous attention owing to nitrogen heteroatom doping. However, it is challenging to estimate the effect of the morphology and porosity of the polydopamine-derived carbon for lithium storage. Here, we designed three polydopamine-derived carbon materials with different morphologies and porosity: carbon nanospheres (CNs), mesoporous carbon nanospheres (MCNs), and bowl-like mesoporous carbon nanoparticles (BMCNs) to evaluate the electrochemical performance. Such a bowl-like mesoporous structure combines multiple advantageous features, including mesoporous channels and shorter transmission distance, thus delivering a high specific capacity. In addition, our work provides new insight into the electrochemical performance of polydopamine-derived carbon and a useful reference for its future application in high-performance lithium ion battery (LIB) electrode materials.

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Section: Resultsmentioning

confidence: 99%

Polydopamine-Derived Carbon: What a Critical Role for Lithium Storage?

et al. 2020

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“…While the topic was not explored further in these systems, experiments performed on LCO suggested that much of the gas effect does derive from the initial cycles, which agrees with what is known about gas evolution in the published literature and cell preparation techniques discussed in the patent literature. 25,27,51,[58][59][60][61] To gain better insights into which gases may contribute strongly to fade in LMO and LCO, cycling was performed in a variety of gases. The capacity fade of LMO based cells was found to be most sensitive to CO 2 and CH 4 , but did not behave accordingly when cycled in the presence of equal compositions of both gases.…”

Section: Discussionmentioning

confidence: 99%

Effects of Commonly Evolved Solid-Electrolyte-Interphase (SEI) Reaction Product Gases on the Cycle Life of Li-Ion Full Cells

Lin

Tang

et al. 2018

J. Electrochem. Soc.

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In this work, it is found that cycling full cells in Ar, versus static conditions, significantly reduces their rate of capacity fade, which is attributed to the removal of gaseous reaction products from the cell. The presence of gases evolved in situ can account for a large fraction of the total capacity fade exhibited by the static cells tested. In attempt to understand the role of specific gaseous species commonly evolved during cycling, LiMn 2 O 4 and LiCoO 2 based full cells were further cycled in Ar-H 2 , Ar-CO, Ar-CO 2 , and Ar-CH 4 at reactive gas compositions between 0.5% and 5% and flow rates high enough to rapidly remove any evolved gas. The different electrodes were sensitive to different gases, the effects of gas composition were non-linear, and the effect of mixing gases was not additive. An attempt was made to correlate the degree of capacity fade with the amount of transition metal deposited on the anode, as measured by secondary ion mass spectrometry, but a strong correlation was not found.

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“…Graphene nanoscroll (GNS), which is a derivative of graphene with a one-dimensional (1D) tubular structure, has received ever-increasing attention from both academia and industry these days. − Owing to its unique 1D topology, GNS exhibits distinct properties from those of pristine graphene by encapsulating various foreign organic or inorganic species into its interior cavity and facilitating the radial expansion of the species to accommodate the increasing volume during the ion intercalation process, along with the open topological structure, leading to wide applications in catalysis, adsorption, environmental protection, ion channels, gas separation, etc. − Recently, it was proposed as a promising electrode material for the Li-ion battery due to its unique characteristics and higher Li-ion storage capability than that of commercial bulk graphite. − However, in order to integrate its real-life devices with practical applications, rational arrangement of individual two-dimensional (2D) planar-structured graphene layers into specific 1D architectures is necessary for converting the remarkable microscopic characteristics of 1D-GNS into macroscopic properties of practical significance.…”

Section: Introductionmentioning

confidence: 99%

Sodium Sulfate Template-Directed Methodology of Rolling Up a Two-Dimensional Graphene Nanosheet into a One-Dimensional Nanoscroll and Its Anode Performance in a Lithium-Ion Battery

Yin

Yan

et al. 2021

ACS Appl. Energy Mater.

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Graphene nanoscroll has received enormous interest due to its potential applications in various fields. However, in practice there still remains a challenge toward cost-efficiency and scale-up production with the existing advanced experimental techniques. Herein, we report an integration methodology to construct a one-dimensional graphene nanoscroll (1D-GNS) from a two-dimensional graphene nanosheet (2D-rGO) via an ingenious template-directed synthesis approach, in which Na2SO4 was used as a sacrificial template for the first time. Na2SO4 was first generated on the surface of reduced graphene oxide (rGO) nanosheets by a combination of antisolvent self-assembly and heat treatment under moderate temperature, in sequence, to shape and maintain the 2D-rGO architecture into an rGO@Na2SO4 composite, which was then immediately quenched into water to dissolve the Na2SO4 template and meanwhile roll up the 2D graphene nanosheets into 1D nanoscrolls spontaneously, followed by a final thermal reduction to reduce the oxygenous groups. The crimping behavior of the 1D-GNS can be conducted by varying the heat-treatment temperature during the quenching process. The as-synthesized 1D-GNS gives quite good electrochemical stability when evaluated as an anode material in a Li-ion battery. This interesting methodology provides an avenue to design and fabricate other scroll-structured nanoarchitectures.

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Tubular Graphene Nano-Scroll Coated Silicon for High Rate Performance Lithium-Ion Battery

Cited by 6 publications

References 41 publications

Polydopamine-Derived Carbon: What a Critical Role for Lithium Storage?

Polydopamine-Derived Carbon: What a Critical Role for Lithium Storage?

Effects of Commonly Evolved Solid-Electrolyte-Interphase (SEI) Reaction Product Gases on the Cycle Life of Li-Ion Full Cells

Sodium Sulfate Template-Directed Methodology of Rolling Up a Two-Dimensional Graphene Nanosheet into a One-Dimensional Nanoscroll and Its Anode Performance in a Lithium-Ion Battery

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