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

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

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 disor...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Vol. 14; no. 20; pp. e1704394 - n/a
Main Authors: Kang, Jun, Kim, Han‐Vin, Chae, Seen‐Ae, Kim, Kwang‐Ho
Format: Journal Article
Language:English
Published: Germany Wiley Subscription Services, Inc 01-05-2018
Subjects:
Agglomerates
Atomic structure
Carbon
carbon material
Diffusion
Lithium
lithium‐doped carbon
Maximization
Nanotechnology
Redesign
Storage capacity
Strategy
superdense state
Transition metal oxides
superdense state
carbon material
lithium-doped carbon
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Summary: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. A novel strategy for maximizing the lithium storage capacity of carbon materials is reported. A high level of Li, 4 wt%, is doped inside carbon to redesign the interior of the carbon material. This results in a remarkably improved Li storage performance using only pure carbon, without the need for the next‐generation materials.
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ISSN:1613-6810
1613-6829
DOI:10.1002/smll.201704394