Carbon-enhanced electrodeposited SnO2/carbon nanofiber composites as anode for lithium-ion batteries

Dirican, Mahmut; Yanılmaz, Meltem; Fu, Kun; Lü, Yao; Kızıl, Hüseyin; Zhang, Xiangwu

doi:10.1016/j.jpowsour.2014.04.102

Cited by 99 publications

(69 citation statements)

References 35 publications

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“…Benefiting from the buffering effect of ZnO nanoparticles, the electrospun composite nanofibers showed improved cyclability and rate capacity. Moreover, graphene sheets [169,170], carbon matrix [171][172][173][174] and metal nanoparticles [175] were also introduced by several groups to further stabilize the structure during cycling and improve electronic conductivity. Zhou and co-workers [176] presented hybrid nanofibers with uniformly embedded SnO x in CNFs (U-SnO x /C nanofibers) as anode materials through electrospinning.…”

Section: Metal Oxidesmentioning

confidence: 99%

Nanostructured electrode materials for lithium-ion and sodium-ion batteries via electrospinning

Zeng

et al. 2016

Sci. China Mater.

127

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Electrospinning has attracted tremendous attention in the design and preparation of 1D nanostructured electrode materials for lithium-ion batteries (LIBs) and sodium-ion batteries (NIBs), due to the versatility and facility. In this review, we present a comprehensive summary of the development of electrospun electrode nanomaterials for LIBs and NIBs, and a brief introduction about electrode materials beyond LIBs and NIBs. By summarizing various electrochemical active materials, this review focuses on the evolution in structures and the constitution of electrospun electrode materials. In detail, a variety of electrospun anode and cathode materials of LIBs and NIBs have been properly discussed, respectively. Finally, the current progress in the electrospun electrode materials is well reviewed and the development direction is also pointed out. We believe that in the nearly future, electrospun electrode materials would be applied in commercial LIBs and promote the advance in NIBs. And we hope that this review could be helpful in the design and fabrication of electrospun hierarchical materials for other advanced energy-storage devices.

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Section: Metal Oxidesmentioning

confidence: 99%

Nanostructured electrode materials for lithium-ion and sodium-ion batteries via electrospinning

Zeng

et al. 2016

Sci. China Mater.

127

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“…Electrosynthesis of tin dioxide is actively used in the formation of anodes of lithium-ion power sources [14]. In [15], authors investigated electrical and structural characteristics of the nanoporous tin dioxide, synthesized as an anode of sodium-ion batteries.…”

Section: Literature Review and Problem Statementmentioning

confidence: 99%

Examining the influence of electrosynthesis conditions on the composition of tin-oxide catalyst

Vargalyuk

Plyasovskaya

Sknar

et al. 2017

EEJET

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“…After this pioneering work, this technology has been improved. In particular, SnO 2 -electrodeposited porous carbon nanofibers (PCNF-SnO 2 ) composites that can maintain their structural stability during repeated charge-discharge cycling have been recently obtained [462]. After coating with amorphous carbon layers by chemical vapor deposition, this PCNF-SnO 2 -C composite delivered capacities of 713, 568, 463, and 398 mAh g À1 , respectively, at 100, 200, 400, and 800 mA g À1 with high capacity retention of 78 % and large coulombic efficiency of 99.8 % at the 100th cycle.…”

Section: Sn Oxidesmentioning

confidence: 99%

Anodes for Li-Ion Batteries

et al. 2016

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Lithium-ion batteries (LiBs) have made considerable progress since the first commercial one by Sony in 1991, which had LiCoO 2 and graphite as active elements of the positive and negative electrodes, respectively. The LiBs are now the primary energy storage devices in the transportation and communications, from portable use in computers, up to electric and hybrid vehicles. More recently, they have also been used as back-up supply units, frequency regulators (load leveling) to integrate on smart grids the electricity produced by windmills and photovoltaic plants (for a recent review, see [1]). These applications require high energy densities, high power, and safety among others. Considerable efforts have been made to propose other electrodes to fulfill these requirements. We have recently reviewed the works and progress concerning the materials for the positive electrode [2][3][4][5][6]. The present work is devoted to the materials for the negative electrode counterpart. It is common to use the terminology anode and cathode for the negative and positive electrodes, respectively, although the electrodes play alternatively the role of anode and cathode during the charge and discharge process. We shall use this terminology in the following for conciseness purposes only.An ideal active anode element should fulfill the following requirements as follows: (1) It must be light and accommodate as much Li as possible to optimize the gravimetric capacity. (2) Its redox potential with respect to Li 0 /Li + must be as small as possible at any Li-concentration. The reason is that this potential is subtracted to the redox potential of the cathode material to give the overall voltage of the cell, and smaller voltage means smaller energy density. (3) It must possess good electronic and ionic conductivities since faster motion of the lithium ions and the electrons also mean higher power density of the cell. (4) It must not be soluble in the solvents of the electrolyte and not react with the lithium salt. (5) It must be safe, i.e. avoid any thermal runaway of the battery, a criterion that is not independent of the previous one, but deserves special attention, especially for use in transportation such as electric vehicles and planes. (6) It must be cheap and environmentally friendly. The different materials proposed as anode elements for Li-ion batteries must be discussed with respect to these different criteria.The graphite is still the most used anode material and is still the reference. The first works giving evidence of the insertion of lithium in graphite date from 1955 [7], confirmed by the synthesis of LiC 6 in 1965 [8]. The synthesis of LiC 6 , however, was not obtained by electrochemical process at that time. Another decade was spent before Besenhard and Eichinger discovered the reversible intercalation of lithium in graphite, proposing this material as an anode in 1976 [9,10]. Increasing the Li content in LiC 6 is possible [8], but no reversible cycling beyond LiC 6 could ever be obtained. The graphite anode can thus be cyc...

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Carbon-enhanced electrodeposited SnO2/carbon nanofiber composites as anode for lithium-ion batteries

Cited by 99 publications

References 35 publications

Nanostructured electrode materials for lithium-ion and sodium-ion batteries via electrospinning

Nanostructured electrode materials for lithium-ion and sodium-ion batteries via electrospinning

Examining the influence of electrosynthesis conditions on the composition of tin-oxide catalyst

Anodes for Li-Ion Batteries

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