Strong, Localized, and Directional Hydrogen Bonds Fluidize Ionic Liquids

Abstract: Hydrogen bonds are very important in chemistry and biology. [1][2][3] The properties of liquids and solutions consisting purely of neutral molecules are characteristically determined by the strength and number of hydrogen bonds. When water freezes to form ice, each water molecule forms four strong hydrogen bonds to its neighbors in tetrahedral fashion giving a periodical H-bond network.[4] In nonpolar solvents peptides retain their helical secondary structure up to very high temperature as a result of intramol… Show more

“…In the real liquid, a distribution of several cation/anion configurations will be present simultaneously [43], and the sketch must be seen as one example of what the data suggest exists in larger amounts. in computational studies [4,5,7,28,29,38]. This suggests that the above findings represent a rather universal phenomenon.…”

“…The list of investigated anions includes bis(trifluoromethylsulfonyl) imide [4][5][6][7], nitrate [8], alkyl sulfates [5,9], dicyanamide [5,10], thiocyanate [5], acetate [11,12], hydrogen sulfate [13,14], and trifluoromethanesulfate [15,16]. On the other hand, interactions with highly symmetrical anions have been studied less.…”

“…The impact of C(2) methylation on the viscosity of imidazolium ionic liquids has been studied extensively, leading to several theories. Fumino's defect theory [7] suggests that the absence of a strong and directional hydrogen bond at C(2) produces a reduced disruption of order. On the other hand, Hunt's reduced entropy theory [28] argues that the methyl group at the C(2) position blocks low energy configurations.…”

Effects of C(2) Methylation on Thermal Behavior and Interionic Interactions in Imidazolium-Based Ionic Liquids with Highly Symmetric Anions

“…In the real liquid, a distribution of several cation/anion configurations will be present simultaneously [43], and the sketch must be seen as one example of what the data suggest exists in larger amounts. in computational studies [4,5,7,28,29,38]. This suggests that the above findings represent a rather universal phenomenon.…”

“…The list of investigated anions includes bis(trifluoromethylsulfonyl) imide [4][5][6][7], nitrate [8], alkyl sulfates [5,9], dicyanamide [5,10], thiocyanate [5], acetate [11,12], hydrogen sulfate [13,14], and trifluoromethanesulfate [15,16]. On the other hand, interactions with highly symmetrical anions have been studied less.…”

“…The impact of C(2) methylation on the viscosity of imidazolium ionic liquids has been studied extensively, leading to several theories. Fumino's defect theory [7] suggests that the absence of a strong and directional hydrogen bond at C(2) produces a reduced disruption of order. On the other hand, Hunt's reduced entropy theory [28] argues that the methyl group at the C(2) position blocks low energy configurations.…”

Effects of C(2) Methylation on Thermal Behavior and Interionic Interactions in Imidazolium-Based Ionic Liquids with Highly Symmetric Anions

“…Imidazolium-based ILs are reported to form ionic hydrogen bonds of the form C(2)-H y A À (A, anion), and bonds formed between 1-ethyl-3-methyl-imidazolium and TFSA anion were reported by Fumino et al 36 Meanwhile, ILs with TFSA anions were reported to possess a significantly smaller cohesive energy density than water. 13 The observation that 1 and 2 are molecularly dispersed in C 4 mimTFSA without forming self-assemblies can be understood by the insufficient difference in cohesive energy between 1, 2 and C 4 mimTFSA.…”

“…It should also be noted that ILs can be amphiphilic 35 and capable of forming ionic hydrogen bonds. 36 We describe herein the formation of bilayer membranes in ILs for a series of aqueous-bilayer-forming cationic glutamate amphiphiles. The intermolecular interactions required for self-assembly in ILs vary depending on the chemical structure of ILs, and these results provide a general guideline to design ordered molecular self-assembly systems in ILs.…”

Controlled self-assembly of amphiphiles in ionic liquids and the formation of ionogels by molecular tuning of cohesive energies

Vibrational Spectroscopy for Studying Hydrogen Bonding in Imidazolium Ionic Liquids and their Mixtures with Cosolvents