posted on 2019-05-29, 00:00authored byJonathan
H. Raberg, Jenel Vatamanu, Stephen J. Harris, Christina H. M. van Oversteeg, Axel Ramos, Oleg Borodin, Tanja Cuk
At
an electrode, ions and solvent accumulate to screen charge,
leading to a nanometer-scale electric double layer (EDL). The EDL
guides electrode passivation in batteries, while in (super)capacitors,
it determines charge storage capacity. Despite its importance, quantification
of the nanometer-scale and potential-dependent EDL remains a challenging
problem. Here, we directly probe changes in the EDL composition with
potential using in situ vibrational spectroscopy and molecular dynamics
simulations for a Li-ion battery electrolyte (LiClO4 in
dimethyl carbonate). The accumulation rate of Li+ ions
at the negative surface and ClO4– ions
at the positive surface from vibrational spectroscopy compares well
to that predicted by simulations using a polarizable APPLE&P force
field. The ion solvation shell structure and ion-pairing within the
EDL differs significantly from the bulk, especially at the negative
electrode, suggesting that the common rationalization of interfacial
electrochemical processes in terms of bulk ion solvation should be
applied with caution.