Density Functional Theory Analysis that Explains the Volume Expansion in Prelithiated Silicon Nanowires

Abstract

This research is a theoretical study that simulates the volume expansion of a prelithiated silicon nanowire during lithium ion insertion and the application of an electric current. Utilizing density functional theory (DFT) the ground state energy Eg (x) of prelithiated silicon (LixSi) is define as a function of the lithium ion (Li+) concentration (x). As the Li+ are increased, Eg (x) becomes increasingly stable from x=1.00 through x=2.415 and decreases in stability as the lithium ion concentration becomes x >2.415 until full lithiation of the silicon nanowire is reached at x=3.75. After the determination of the lithiated silicon ground state energies an electric current is applied to the lithiated silicon nanowire at varies Li+ concentrations x. It was discovered that the volume expansion began at approximately x=3.25 and increased to over 300% of the original volume of a pristine silicon nanowire at x=3.75 which at this point was full lithiation. This is in sharp contrast to prior research studies where the ground state energy was not considered. In previous studies the computation of the volume expansion starts approximately at x=0.75 and produces a continuous nonlinear volume expansion until the process was terminated at full lithiation.