1. Ex Situ Investigation of Anisotropic Interconnection in Silicon-Titanium-Nickel Alloy Anode Material.
- Author
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Jong-Soo Cho, Pankaj Kumar Alaboina, Chan-Soon Kang, Seul-Cham Kim, Seoung-Bum Son, Soonsung Suh, Jaehyuk Kim, Seunguk Kwon, Se-Hee Lee, Kyu-Hwan Oh, and Sung-Jin Cho
- Subjects
MELT spinning ,LITHIUM-ion batteries ,TITANIUM-silicon alloys - Abstract
Herein we investigate the nanostructural evolution of Silicon-Titanium-Nickel (Si-Ti-Ni) ternary alloy material synthesized by melt spinning process for advanced lithium-ion battery anode. The synthesized material was found to have nano-Silicon particles dispersed in the Ti
4 Ni4 Si7 (STN) alloy buffering matrix and was characterized by X-ray diffraction (XRD), High resolution- transmission electron microscope (HR-TEM), Scanning transmission electron microscopes - energy dispersive X-ray spectrometer (STEM-EDS), and electrochemical performance test. The role of STN matrix is to accommodate the volume expansion stresses of the dispersed Si nanoparticles. However, an interesting behavior was observed during cycling. The Si nanoparticles were observed to form interconnection channels growing through the weak STN matrix cracks and evolving to a network isolating the STN matrix into small puddles. This unique nanostructural evolution of Si particles and isolation of the STN matrix failing to offer significant buffering effect to the grown Si network eventually accelerates more volume expansions during cycling due to less mechanical confinement and leads to performance degradation and poor cycle stability. [ABSTRACT FROM AUTHOR]- Published
- 2017
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