Critical Insight into the Relentless Progression Toward Graphene and Graphene‐Containing Materials for Lithium‐Ion Battery Anodes

Raccichini, Rinaldo; Varzi, Alberto; Wei, Di; Passerini, Stefano

doi:10.1002/adma.201603421

Cited by 138 publications

(76 citation statements)

References 423 publications

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“…[5] To increase the energy and power densities of LIBs, great efforts have been devoted to develop various alternatives to graphite, among which nanostructured carbon materials have received intensive interest due to their high electrical conductivity, low cost, designable structure, and porosity, etc. [5,6] Particularly, 2D ultrathin layer structure can enhance Li-storage ability by bounding Li not only on both sides of nanosheets, but also on the edges, defects, and covalent sites of nanosheets, while the 3D porous network can provide multidimensional electron transport pathway and shorten ion diffusion distance to promote the electrochemical reaction throughout the entire electrode. [7][8][9][10] Meanwhile, the introduction of heteroatom (e.g., N, B, S, F, and P) has been considered as another versatile approach to tune the intrinsic molecular structure of carbon materials, which can create more active sites and increase the electrode/electrolyte affinity and thus improve the Li storage properties to different extent depending on the specific synthetic conditions.…”

Section: Doi: 101002/smll201703969mentioning

confidence: 99%

“…Graphite, the commercial anode material, cannot meet the increasing demands of rapidly developing LIB markets due to its low theoretical specific capacity (372 mA h g −1 ) and poor rate capability . To increase the energy and power densities of LIBs, great efforts have been devoted to develop various alternatives to graphite, among which nanostructured carbon materials have received intensive interest due to their high electrical conductivity, low cost, designable structure, and porosity, etc . Particularly, 2D ultrathin layer structure can enhance Li‐storage ability by bounding Li not only on both sides of nanosheets, but also on the edges, defects, and covalent sites of nanosheets, while the 3D porous network can provide multidimensional electron transport pathway and shorten ion diffusion distance to promote the electrochemical reaction throughout the entire electrode .…”

Section: Introductionmentioning

confidence: 99%

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Ultrathin Nitrogen‐Doped Carbon Layer Uniformly Supported on Graphene Frameworks as Ultrahigh‐Capacity Anode for Lithium‐Ion Full Battery

Huang

Yang

et al. 2018

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The designable structure with 3D structure, ultrathin 2D nanosheets, and heteroatom doping are considered as highly promising routes to improve the electrochemical performance of carbon materials as anodes for lithium-ion batteries. However, it remains a significant challenge to efficiently integrate 3D interconnected porous frameworks with 2D tunable heteroatom-doped ultrathin carbon layers to further boost the performance. Herein, a novel nanostructure consisting of a uniform ultrathin N-doped carbon layer in situ coated on a 3D graphene framework (NC@GF) through solvothermal self-assembly/polymerization and pyrolysis is reported. The NC@GF with the nanosheets thickness of 4.0 nm and N content of 4.13 at% exhibits an ultrahigh reversible capacity of 2018 mA h g at 0.5 A g and an ultrafast charge-discharge feature with a remarkable capacity of 340 mA h g at an ultrahigh current density of 40 A g and a superlong cycle life with a capacity retention of 93% after 10 000 cycles at 40 A g . More importantly, when coupled with LiFePO cathode, the fabricated lithium-ion full cells also exhibit high capacity and excellent rate and cycling performances, highlighting the practicability of this NC@GF.

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Section: Doi: 101002/smll201703969mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Ultrathin Nitrogen‐Doped Carbon Layer Uniformly Supported on Graphene Frameworks as Ultrahigh‐Capacity Anode for Lithium‐Ion Full Battery

Huang

Yang

et al. 2018

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“…Among the electrode materials, the anode can be classified into five categories depending on the reaction mechanism used for storing Li: (a) Li intercalation into graphite, (b) insertion of Li into high-voltage oxides (e.g., TiO 2 ), (c) materials forming alloys with Li (e.g., Si), (d) materials that undergo conversion reactions with Li (e.g., Fe 3 O 4 ), and (e) Li storage in reduced graphene oxide (RGO) ( Figure S1, Supporting Information). [8] Materials belonging to each category present some inherent characteristics not observed in materials of different categories, while also presenting some disadvantages in terms of their practical use. For example, although commercialized graphite is the most common anode material used in LIBs, it cannot satisfy the current demands because of its low theoretical capacity (372 mA h g −1 ) and poor rate performance.…”

Section: Doi: 101002/smll201704394mentioning

confidence: 99%

“…To satisfy these urgent requirements, there have been intensive efforts to develop new and better electrodes. Among the electrode materials, the anode can be classified into five categories depending on the reaction mechanism used for storing Li: (a) Li intercalation into graphite, (b) insertion of Li into high‐voltage oxides (e.g., TiO 2 ), (c) materials forming alloys with Li (e.g., Si), (d) materials that undergo conversion reactions with Li (e.g., Fe 3 O 4 ), and (e) Li storage in reduced graphene oxide (RGO) (Figure S1, Supporting Information) …”

Section: Introductionmentioning

confidence: 99%

A New Strategy for Maximizing the Storage Capacity of Lithium in Carbon Materials

Kang

Kim

Chae

et al. 2018

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A novel strategy for maximizing the lithium storage capacity of carbon materials is reported. To redesign the interior structure, a large amount of Li, 4 wt%, is doped into the carbon during its synthesis. The Li-doped carbon is subsequently annealed, during which the diffusion of Li induces a disordered structure, thereby generating many nanocavities. The diffused Li atoms aggregate into a superdense state within the carbon structure; when the Li agglomerates escape from the carbon during the delithiation process, new void spaces are created at their location. Thus, the interior of carbon is evacuated to form a new structure capable of storing a large amount of Li, realizing a high reversible capacity during charging. At a rate of 1 C, the average reversible capacity of the material is three times higher than that of commercial graphite, with a stable cycling performance over 300 cycles. This is a remarkably improved Li storage performance for pure carbon, without the need for the silicon, tin, or transition metal oxide, that are becoming popular as next-generation materials. Therefore, this novel strategy can potentially aid in the design of high-performance materials via better carbon material design and combinations with other types of materials.

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“…[1,2] Despite these advantages, the limited lithium resource on earth restricts the applications of LIBs severely.I nview of this, researchers have made great efforts to explore alternative energy storages ystems. [1,2] Despite these advantages, the limited lithium resource on earth restricts the applications of LIBs severely.I nview of this, researchers have made great efforts to explore alternative energy storages ystems.…”

Section: Introductionmentioning

confidence: 99%

Three‐Dimensional Graphene‐based N‐doped Carbon Composites as High‐Performance Anode Materials for Sodium‐ion Batteries

Chang

Chen

Zhou

et al. 2018

Chemistry An Asian Journal

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An itrogen-doped carbon layer coating on a3 D graphene framework (NCL@GF) was produced by the in-situ polymerizationo fau niform polyimide layer on the graphene framework surface and ac arbonization process. The NCL@GF exhibited a3 Dm acroporous structure with uniform N-doped porousc arbonl ayers and ah igh 5.4 at. %n itrogen content, which not only effectively enhanced the active sites but also facilitated fast ion ande lectron transporti nt he 3D pathways. Consequently,t he NCL@GF as the anode of a sodium-ion battery (SIB) exhibited ad ischarge capacity of 357 mAh g À1 at 0.1 Ag À1 after 200 cycles, ar emarkable rate capability with ac apacity of 122 mAh g À1 at 8Ag À1 ,a nd a super long cyclel ifew ithacapacity retention of 70 %c apacity after 2500 cycles at 0.5 Ag À1 .S uch performance is superiort ot hat of previously reported carbon or graphenebased composites.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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Critical Insight into the Relentless Progression Toward Graphene and Graphene‐Containing Materials for Lithium‐Ion Battery Anodes

Cited by 138 publications

References 423 publications

Ultrathin Nitrogen‐Doped Carbon Layer Uniformly Supported on Graphene Frameworks as Ultrahigh‐Capacity Anode for Lithium‐Ion Full Battery

Ultrathin Nitrogen‐Doped Carbon Layer Uniformly Supported on Graphene Frameworks as Ultrahigh‐Capacity Anode for Lithium‐Ion Full Battery

A New Strategy for Maximizing the Storage Capacity of Lithium in Carbon Materials

Three‐Dimensional Graphene‐based N‐doped Carbon Composites as High‐Performance Anode Materials for Sodium‐ion Batteries

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