posted on 2021-04-29, 15:03authored byFei Shuang, Katerina E. Aifantis
This is the first study that employs
large-scale atomistic simulations
to examine the stress generation and deformation mechanisms of various
Si nanopillars (SiNPs) during Li-ion insertion. First, a new robust
and effective minimization approach is proposed to relax a lithiated
amorphous SiNP (a-SiNP), which outperforms the known methods. Using
this new method, our simulations are able to successfully capture
the experimental morphological changes and volume expansions that
SiNPs, hollow a-SiNPs, and solid crystalline SiNPs (c-SiNPs) experience
upon maximum lithiation. These simulations enable us to selectively
track the displacement of Si atoms and their atomic shear strain in
the Li3.75Si alloy region, allowing us to observe the plastic
flow and illustrate the atomistic mechanism of lithiation-induced
deformation for various SiNPs for the first time. Based on the simulation
results, a simple fracture mechanistic model is used to determine
the fracture resistance of SiNPs, showing that the hollow a-SiNP is
the optimal form of Si as an anode because it has the highest fracture
resistance. The crack propagation simulation suggests that the preexisting
dislocations in pristine c-Si can contribute toward the fracture of
c-SiNPs during lithiation. These findings can guide the design of
new Si-based anode geometries for the next-generation Li-ion batteries.