Electrospun porous carbon nanofibers as lithium ion battery anodes

Peng, Yi; Lo, Chieh Tsung

doi:10.1007/s10008-015-2976-7

Cited by 63 publications

(35 citation statements)

References 48 publications

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“…6, the adsorption occurring was at relative pressure smaller than 0.2 because of the micropores, and mesopores lead to the adsorption occurring at relative pressure larger than 0.8. 54 The results showed that the exists macropore and hierarchical pores in rGO/CSn. Table 1 showed the specic surface area and the porosity parameters.…”

Section: Bet Analysis Of Rgo/csnmentioning

confidence: 95%

Fabrication of macroporous reduced graphene oxide composite aerogels reinforced with chitosan for high bilirubin adsorption

Song

Cui

et al. 2018

RSC Adv.

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Section: Bet Analysis Of Rgo/csnmentioning

confidence: 95%

Fabrication of macroporous reduced graphene oxide composite aerogels reinforced with chitosan for high bilirubin adsorption

Song

Cui

et al. 2018

RSC Adv.

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“…The layered structure of graphite [6] U poslednje vreme se ulažu veliki napori sa ciljem da se povećaju radne performanse i kapacitet anodnog materijala u Li-jonskoj bateriji. Među novim anodnim materijalima su: ugljenične nanocevi [32], ugljenična nanovlakna [33], grafen [34], porozni ugljenik [35], silicijum-oksid [36], silikon [37], germanijum [38], kalaj [39], oksidi prelaznih metala [40], metalni sulfidi [41], fosfidi [42], nitridi [43] itd. Radne performanse nekih od najčešće korišćenih anodnih materijala su date u tabeli 2, dok je na slici 5 dato poređenje elektrohemijskih osobina katodnih i anodnih materijala.…”

Section: Anodaunclassified

Recycling of cathode material from spent lithium-ion batteries

Medic¹,

Dimitrijević²,

Spalović³

et al. 2018

Zaštita materijala

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Reciklaža katodnog materijala iz istrošenih litijum-jonskih baterija IZVOD U ovom radu je prikazana struktura i princip rada Li-jonskih baterija. Dat je kratak pregled razvoja katodnih i anodnih materijala i izneti su zahtevi koje je potrebno da separator i elektrolit ispune kako bi se koristili u Li-jonskim baterijama. Takođe, u radu su prikazani svi stadijumi u procesu reciklaže Li-jonskih baterija, sa posebnim osvrtom na hidrometalurški tretman katodnog materijala i valorizaciju litijuma i kobalta.

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“…Particularly, 1D carbon nanofibers have been considered as one type of carbon due to their 1D conductive nanostructure conducive to by facilitating electrolyte transportation and electron transfer . Typically, electrospinning technology is a reliable and versatile method in fabricating 1D nanostructured polymer, which can be easily converted into conductive carbon nanofibers by the further pyrolysis process . Additionally, the heteroatoms (e.g., phosphorous, sulfur, and nitrogen) doped in carbon architecture is also an effective way to tune their physicochemical properties by expanding the graphite‐like interlayer distance, introducing ample defects and porosities, and enhancing electric conductivity, which are of benefit for improving the reversible capacity and rate capability …”

Section: Introductionmentioning

confidence: 99%

N‐Doped Carbon Nanofibers with Interweaved Nanochannels for High‐Performance Sodium‐Ion Storage

Zhao

et al. 2019

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advantages of high voltage, low self-discharge, and high energy density. However, the low lithium reserves and high cost can hardly satisfy the ever-growing energy storage markets especially for the largescale energy storage and renewable energy grid. [3][4][5] Recently, sodium ion batteries (SIBs) have triggered tremendous attentions due to their earth abundant, low cost, and similar chemical properties to lithium. [6][7][8] To date, ample potential anode materials for SIBs have been explored, such as alloys (Sn, [9,10] Sb, [11] Ge [12] ), metal oxides and sulfides, [13][14][15][16] carbon-based materials [17,18] and so on. Among them, carbon-based materials have represented the most competitive anode due to the features of abundance, low potential and low cost. However, the limited reversible capacities and the rather low initial columbic efficiency as well as the poor rate performance still impede the practical application of most carbon materials, which is attributed to the large ionic radius of Na + (1.02 Å) compared with that of Li + (0.76 Å). In this regard, one of the most critical issue for the development of SIBs is how to design and develop engineered carbon anode materials for fast Na + insertion and extraction. [19] So far, numerous carbon materials with different morphologies and structure, such as 1D carbon nanofibers, [20,21] 2D expanded graphite, [22,23] and 3D carbon nanospheres, [24] have been investigated as anode of SIBs in the hope to enhance the associated electrochemical performance. Particularly, 1D carbon nanofibers have been considered as one type of carbon due to their 1D conductive nanostructure conducive to by facilitating electrolyte transportation and electron transfer. [25,26] Typically, electrospinning technology is a reliable and versatile method in fabricating 1D nanostructured polymer, which can be easily converted into conductive carbon nanofibers by the further pyrolysis process. [27] Additionally, the heteroatoms (e.g., phosphorous, [28,29] sulfur, [30,31] and nitrogen [32,33] ) doped in carbon architecture is also an effective way to tune their physicochemical properties by expanding the graphite-like interlayer distance, introducing ample defects and porosities, and enhancing electric conductivity, which are of benefit for improving the reversible capacity and rate capability. [34] Bearing the points above in mind, we herein report a welldesigned synthetic route for fabricating nitrogen-rich carbon Although graphite materials have been applied as commercial anodes in lithium-ion batteries (LIBs), there still remain abundant spaces in the development of carbon-based anode materials for sodium-ion batteries (SIBs). Herein, an electrospinning route is reported to fabricate nitrogendoped carbon nanofibers with interweaved nanochannels (NCNFs-IWNC) that contain robust interconnected 1D porous channels, produced by removal of a Te nanowire template that is coelectrospun within carbon nanofibers during the electrospinning process. The NCNFs-IWNC features favorable properties, in...

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Electrospun porous carbon nanofibers as lithium ion battery anodes

Cited by 63 publications

References 48 publications

Fabrication of macroporous reduced graphene oxide composite aerogels reinforced with chitosan for high bilirubin adsorption

Fabrication of macroporous reduced graphene oxide composite aerogels reinforced with chitosan for high bilirubin adsorption

Recycling of cathode material from spent lithium-ion batteries

N‐Doped Carbon Nanofibers with Interweaved Nanochannels for High‐Performance Sodium‐Ion Storage

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