posted on 2019-01-04, 00:00authored byAlta Fang, Alex Smolyanitsky
The performance of
electric double-layer capacitors is strongly
influenced by the choice of electrolyte, and electrolytes comprised
of ionic liquid mixtures have shown promise for enabling high energy
densities. Here we perform all-atom molecular dynamics simulations
of ionic liquids containing 1-ethyl-3-methylimidazolium and different
fractions of bis(trifluoromethylsulfonyl)imide and tetrafluoroborate,
in conjunction with planar graphene sheets as electrodes. We demonstrate
that relative ion–electrode van der Waals interactions play
an important role in the population of ions adsorbed in the first
interfacial layer near uncharged electrodes. Near charged electrodes,
we find that the ionic liquid mixtures generally exhibit integral
capacitances intermediate between the two pure ionic liquids. We characterize
cumulative ion densities near electrodes carrying various surface
charges, revealing different charging mechanisms for different ionic
liquids, which we relate to the relative sizes of the ions. Finally,
in the ionic liquid mixtures we identify an effective ion exchanging
phenomenon wherein charging of the electrodes leads to different trends
in the densities of the two types of anions in the first interfacial
layer, which enhances counterion adsorption and improves capacitance
at the negative electrode.