Silicon
(Si) has gained huge attention as an anode material for next-generation
high-capacity lithium-ion batteries (LIBs). However, despite its overwhelming
beneficial features, its large-scale commercialization is hampered
due to unavoidable challenges such as colossal volume change during
(de)alloying, inherent low electronic and ionic conductivities, low
Coulombic efficiency, unstable/dynamic solid electrolyte interphase
(SEI), electrolyte drying and so forth. Among other strategies, the
use of a fraction dose of chemical additives is hailed as the most
effective, economic and scalable approach to realize Si-anode-based
LIBs. Functional additives can modify the nature and chemical composition
of the SEI, which in turn dictates the obtainable capacity, rate capability,
Coulombic/energy efficiency, safety, and so forth of the battery system.
Thus, we report a systematic and comparative investigation of various
electrolyte additives, namely tetraethoxysilane (TEOS), (2-cyanoethyl)triethoxysilane
(TEOSCN), vinylene carbonate (VC), fluoroethylene carbonate (FEC),
and a blend of TEOSCN, VC, and FEC (i.e., VC/FEC/TEOSCN) using electrochemical
analysis, X-ray photoelectron spectroscopy, density functional theory
calculation, and differential scanning calorimetry. The ternary mixture
(FEC/VC/TEOSCN) results in a thinner SEI layer consisting of high
shear modulus SEI-building species (mainly LiF). It also provides
much improved thermal stability amid all tested additives, showing
its potentiality to enable high capacity and safer Si-based anode
LIBs. Thus, nitrile-functionalized silanes are highly promising electrolyte
additives to boost the electrochemical performance and safety-induced
risks of Si-based anode LIBs, emanating from the formation of a robust
SEI layer.
