Silicon (Si) films are promising anode materials in thin-film lithium batteries due to their high capacity of 3578 mAh g-1, but the huge volume expansion of lithiated Li15Si4 and the unstable solid electrolyte interphase (SEI) preclude their practical application. Here lithium fluoride (LiF) coated Si nanocolumns are fabricated by glancing angle evaporation to address the obstacle. The LiF coating can elevate the lithium ion diffusion coefficient (LDC) of Si electrodes upon the alloying reaction and reduce the LDC upon the SEI formation. The composition evolution of the outer SEI layer in the LiF/Si electrodes is studied by ex situ X-ray photoelectron spectroscopy. The modified surface and mitigated volume expansion enable the LiF/Si nanocolumns to exhibit superior rate capability and higher cycling stability compared with the pristine Si nanocolumns. This work demonstrates the positive effect of LiF coating for reducing the polarization and forming a robust SEI film on Si anodes.
Keywords: X-ray photoelectron spectroscopy; lithium fluoride; lithium ion diffusion coefficient; silicon nanocolumn; solid electrolyte interphase.