论文信息 - Small particle size multiphase Li-alloy anodes for lithium-ionbatteries

Small particle size multiphase Li-alloy anodes for lithium-ionbatteries

An impressive improvement of the cycling performance of Li-alloy anodes (M + Li+ +e− ⇆ LixM) in rechargeable organic electrolyte lithium batteries can be achieved by replacing compact or large particle size metallic host matrices M (e.g. Sn or Sb) with small particle size (micro- or nano-scale) multiphase metallic host materials like SnSnSbn or SnSnAgn. Electrochemical alloy deposition is a convenient way to prepare sub-micrometer particles of Sn and SnSbn or Sn and SnAgn. During the first lithium insertion these small particle size multiphase matrix materials are expanded to a porous material, however, without formation of major cracks. This seems not only to be related with the small absolute changes in the size of the individual particles, but also with the fact that the more reactive particles are allowed to expand in a soft and ductile surrounding of still unreacted material.

[1] W. C. Maskell,et al. Cycling Behavior of Thin Film LiAl Electrodes with Liquid and Solid Electrolytes , 1985 .

[2] W. Müller-Warmuth,et al. Progress in Intercalation Research , 1994 .

[3] H. Fritz,et al. Reversibles elektrochemisches legieren von metallen der V. hauptgruppe in organischen Li+—Lösungen , 1975 .

[4] A. Kozawa,et al. Cycling performance of the LixAl anode prepared by the compression method , 1994 .

[5] H. A. Christopher,et al. Lithium‐Aluminum Electrode , 1977 .

[6] M. Hansen,et al. Constitution of Binary Alloys , 1958 .

[7] J. Besenhard,et al. Cycling of β-LiAl in organic electrolytes — effect of electrode contaminations and electrolyte additives , 1985 .

[8] T. Jow,et al. Composite Electrodes Containing Conducting Polymers and Li Alloys , 1988 .

[9] R. Huggins,et al. Behavior of Some Binary Lithium Alloys as Negative Electrodes in Organic Solvent‐Based Electrolytes , 1986 .

[10] W. C. Maskell,et al. Thin film lithium aluminium negative plate material , 1984 .

[11] R. Huggins. Materials science principles related to alloys of potential use in rechargeable lithium cells , 1989 .