Anisotropic Swelling and Fracture of Silicon Nanowires during Lithiation

Xiao Hua Liu; Zheng He; Li Zhong; Shan Huang; Khim Karki; Liqiang Zhang; Yang Liu; Akihiro Kushima; Wen Tao Liang; Jiangwei Wang; Jeong‐Hyun Cho; Eric S. Epstein; Shadi A. Dayeh; S. T. Picraux; Ting Zhu; Ju Li; John P. Sullivan; John Cumings; Chunsheng Wang; Scott X. Mao; Zhi Zhen Ye; Sulin Zhang; Jian Yu Huang

doi:10.1021/nl201684d

Anisotropic Swelling and Fracture of Silicon Nanowires during Lithiation

Xiao Hua Liu(Sandia National Laboratories), Zheng He(University of Pittsburgh), Li Zhong(University of Pittsburgh), Shan Huang(Georgia Institute of Technology), Khim Karki(University of Maryland, College Park), Liqiang Zhang(University of Pittsburgh), Yang Liu(Sandia National Laboratories), Akihiro Kushima(University of Pennsylvania), Wen Tao Liang(Pennsylvania State University), Jiangwei Wang(University of Pittsburgh), Jeong‐Hyun Cho(Los Alamos National Laboratory), Eric S. Epstein(University of Maryland, College Park), Shadi A. Dayeh(Los Alamos National Laboratory), S. T. Picraux(Los Alamos National Laboratory), Ting Zhu(Georgia Institute of Technology), Ju Li(University of Pennsylvania), John P. Sullivan(Sandia National Laboratories), John Cumings(University of Maryland, College Park), Chunsheng Wang(University of Maryland, College Park), Scott X. Mao(University of Pittsburgh), Zhi Zhen Ye(Zhejiang University), Sulin Zhang(Pennsylvania State University), Jian Yu Huang(Sandia National Laboratories)

Nano Letters

June 27, 2011

10.1021/nl201684d

Cited by 803

Abstract

We report direct observation of an unexpected anisotropic swelling of Si nanowires during lithiation against either a solid electrolyte with a lithium counter-electrode or a liquid electrolyte with a LiCoO(2) counter-electrode. Such anisotropic expansion is attributed to the interfacial processes of accommodating large volumetric strains at the lithiation reaction front that depend sensitively on the crystallographic orientation. This anisotropic swelling results in lithiated Si nanowires with a remarkable dumbbell-shaped cross section, which develops due to plastic flow and an ensuing necking instability that is induced by the tensile hoop stress buildup in the lithiated shell. The plasticity-driven morphological instabilities often lead to fracture in lithiated nanowires, now captured in video. These results provide important insight into the battery degradation mechanisms.

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