Metallic aluminum (Al) have been explored as potential anode materials for lithium storage because of its high theoretical capacity (993 mAh g–1) and low voltage plateaus. Al possesses high electric… Click to show full abstract
Metallic aluminum (Al) have been explored as potential anode materials for lithium storage because of its high theoretical capacity (993 mAh g–1) and low voltage plateaus. Al possesses high electric conductivity, low cost and environmental friendliness. Unfortunately, Al suffers from huge volume change (>100%) during the lithiation/delithiation process, which inevitably results in the pulverization of electrode and rapid capacity decay during cycling processes. To circumvent above issues, a simple but efficient strategy is demonstrated to fabricate free-standing multi-atomic layers of metallic Al by harnessing the good ductility of Al under pressure. The resultant multi-atomic Al layers are ultrathin, ≈3 nm, and have a large aspect ratio. Such unique features enable multi-atomic Al nanosheets to construct uniform and compact films with graphene. Thus, the hybrid films with different ratios are achieved, in which the notorious volume change of metallic Al can be efficiently circumvented via the good flexibility of graphene, and the density of whole electrode can be significantly enhanced. As a consequence, the optimized multi-atomic Al layers-graphene (AlL-G) film exhibits a very high volumetric capacity of 1089 mAh cm–3, high-rate capability and ultralong cycle life up to 20 000 cycles for lithium storage.
               
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