Electrochemical properties of nanostructured Al1-x Cu x alloys as anode materials for rechargeable lithium-ion batteries

C. Y. Wang; Y. S. Meng; G. Ceder; Y. Li

doi:10.1149/1.2943215

Electrochemical properties of nanostructured Al_1-x Cu _x alloys as anode materials for rechargeable lithium-ion batteries

C. Y. Wang
, Y. S. Meng
, G. Ceder
, Y. Li

Research output: Contribution to journal › Article › peer-review

53 Scopus citations

Abstract

The key challenge to use metallic alloys as anodes in rechargeable lithium batteries is to improve their cycling ability without compromising their high specific capacity. We suggest that an important parameter controlling these two properties is the magnitude of interaction between the active and the inactive components in the alloy system. We demonstrated these ideas on the Al-Cu system by investigating the structure and electrochemical properties of sputtered Al_1-x Cu_x (0 < x < 0.37) thin-film alloys. The optimum composition is determined to be ∼20 at % Cu. A specific capacity of 792 mAh/g has been obtained for nanostructured Al_0.8Cu_0.2 with capacity retention of ∼50% after 100 cycles. The formation of a supersaturated solid solution structure is also suggested to enhance the electrochemical performance.

Original language	English
Pages (from-to)	A615-A622
Journal	Journal of the Electrochemical Society
Volume	155
Issue number	9
DOIs	https://doi.org/10.1149/1.2943215
State	Published - 2008
Externally published	Yes

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abstract = "The key challenge to use metallic alloys as anodes in rechargeable lithium batteries is to improve their cycling ability without compromising their high specific capacity. We suggest that an important parameter controlling these two properties is the magnitude of interaction between the active and the inactive components in the alloy system. We demonstrated these ideas on the Al-Cu system by investigating the structure and electrochemical properties of sputtered Al1-x Cux (0 < x < 0.37) thin-film alloys. The optimum composition is determined to be ∼20 at \% Cu. A specific capacity of 792 mAh/g has been obtained for nanostructured Al0.8Cu0.2 with capacity retention of ∼50\% after 100 cycles. The formation of a supersaturated solid solution structure is also suggested to enhance the electrochemical performance.",

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AU - Wang, C. Y.

AU - Meng, Y. S.

AU - Ceder, G.

AU - Li, Y.

PY - 2008

Y1 - 2008

N2 - The key challenge to use metallic alloys as anodes in rechargeable lithium batteries is to improve their cycling ability without compromising their high specific capacity. We suggest that an important parameter controlling these two properties is the magnitude of interaction between the active and the inactive components in the alloy system. We demonstrated these ideas on the Al-Cu system by investigating the structure and electrochemical properties of sputtered Al1-x Cux (0 < x < 0.37) thin-film alloys. The optimum composition is determined to be ∼20 at % Cu. A specific capacity of 792 mAh/g has been obtained for nanostructured Al0.8Cu0.2 with capacity retention of ∼50% after 100 cycles. The formation of a supersaturated solid solution structure is also suggested to enhance the electrochemical performance.

AB - The key challenge to use metallic alloys as anodes in rechargeable lithium batteries is to improve their cycling ability without compromising their high specific capacity. We suggest that an important parameter controlling these two properties is the magnitude of interaction between the active and the inactive components in the alloy system. We demonstrated these ideas on the Al-Cu system by investigating the structure and electrochemical properties of sputtered Al1-x Cux (0 < x < 0.37) thin-film alloys. The optimum composition is determined to be ∼20 at % Cu. A specific capacity of 792 mAh/g has been obtained for nanostructured Al0.8Cu0.2 with capacity retention of ∼50% after 100 cycles. The formation of a supersaturated solid solution structure is also suggested to enhance the electrochemical performance.

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Electrochemical properties of nanostructured Al_1-x Cu _x alloys as anode materials for rechargeable lithium-ion batteries

Abstract

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