4.5 Article

Molecular-level insights into composition-dependent structure, dynamics, and hydrogen bonds of binary ionic liquid mixture from molecular dynamics simulations

Journal

CHEMICAL PHYSICS
Volume 542, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.chemphys.2020.111051

Keywords

Molecular dynamics simulation; Ionic liquid mixture; Hydrogen bond; Molar fraction

Funding

  1. National Natural Science Foundation of China [21463011, 21863005]
  2. Natural Science Foundation of Jiangxi Province [20171BAB203012]
  3. Special Program for Applied Research on Super Computation of the NSFC-Guangdong Joint Fund (the second phase) [U1501501]
  4. Sponsored Program for Cultivating Youths of Outstanding Ability in Jiangxi Normal University

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In this study, molecular dynamics simulations were conducted to investigate the structure, dynamics, and hydrogen bonds in imidazolium-based ionic liquid mixtures with varying concentrations of [BF4](-) anions. The results revealed that as the concentration of [BF4](-) anions increased, the association extent between cations and anions weakened, leading to faster rotation speeds.
In this work, we have performed a series of molecular dynamics (MD) simulations to explore structure, dynamics, and hydrogen bonds (HBs) of the imidazolium-based ionic liquid (IL) mixture containing [Emim] [BF4](x) [NTF2]((1-x)), where the molar fraction x is 0.0, 0.25, 0.50, 0.75, and 1.0, respectively. Our simulation results demonstrate that the association extent between cations and both anions become weaker and weaker as the concentration of [BF4](-) anion increases due to the weakened interactions between them. Meanwhile, all ions in the IL mixture are found to diffuse faster at the higher concentration of [[BF4]- anion while the order of diffusion rate is always [Emim](+) > [BF4](-) > [NTF2](-) owing to different molecular weights regardless of the composition. Furthermore, the weakened HBs between cations and anions are found to be at the higher concentration of [BF4](-) anion, leading to a faster rotation for all ions in the IL mixture. Compared to the diffusion rates among different ions, however, there is unexpectedly a much larger difference in their rotation rates with the fixed order of [BF4](-) > [Emim](+) > [NTF2](-), where the rotational relaxation times of [Emim](+) and [NTF2](-) are much more than that of [BF4](-) by at least one order of magnitude. This can be attributed to that the rotational motions of spherical [BF4](-) anions only require the transient HB breakage with cations so that their rotations should be affected by the continuous HB strength, which is significantly different from those of both [Emim](+) and [NTF2](-) dominated by the intermittent HB strength. Our simulation results provide a molecular-level understanding composition-dependent structure, dynamics, and HBs in IL mixtures.

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