Triphilic Ionic‐Liquid Mixtures: Fluorinated and Non‐fluorinated Aprotic Ionic‐Liquid Mixtures

Hollóczki, Oldamur; Macchiagodena, Marina; Weber, Henry; Thomas, Martin A.; Brehm, Martin; Stark, Annegret; Russina, Olga; Triolo, Alessandro; Kirchner, Barbara

doi:10.1002/cphc.201500473

Cited by 112 publications

(132 citation statements)

References 65 publications

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“…The newly implemented domain analysis in TRAVIS [39] allowed analysiso f the domains in terms of their numbers and their shape on aq ualitative and also quantitative basis. Furthermore, in as ubsequenta rticle [47] we apply this analysis to triphilic ionic-liquidm ixtures, which are obtained from fluorinated andn on-fluorinated aprotic ionic liquids. The alkyl side chains, however, show completely different aggregation behavior.A lthough the fluorouss ide chains are also more or less connected in one or maximally in two domains, the alkyl phases are dispersed in al arge amount of domains that are more spherical than the other domains.…”

Section: Discussionmentioning

confidence: 99%

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Domain Analysis in Nanostructured Liquids: A Post‐Molecular Dynamics Study at the Example of Ionic Liquids

et al. 2015

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In the present computational work, we develop a new tool for our trajectory analysis program TRAVIS to analyze the well-known behavior of liquids to separate into microphases. The dissection of the liquid into domains of different subsets, for example, in the case of fluorinated ionic liquids with anionic and cationic head groups (forming together the polar domain), fluorous, and alkyl subsets is followed by radical Voronoi tessellation. This leads to useful average quantities of the subset neighbor count, that is, the domain count that gives the amount of particular domains in the liquid, the domain volume and surface, as well as the isoperimetric quotient, which provides a measure of the deviation of the domains from a spherical shape. Thus, the newly implemented method allows analysis of the domains in terms of their numbers and shapes on a qualitative and also quantitative basis. It is a simple, direct, and automated analysis that does not need evaluation of the structure beforehand in terms of, for example, first solvent shell minima. In the microheterogeneous ionic liquids that we used as examples, the polar subsets always form a single domain in all investigated liquids. Although the fluorous side chains are also more or less connected in one or, maximally, two domains, the alkyl phases are dispersed.

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Section: Discussionmentioning

confidence: 99%

“…The polar region (including the anion and the head group of the cation) always forms as ingle domain in the liquids, in the form of lengthy, more nonspherical channels. [47] Thus, with this newly developed analysis tool we are now ablet oo btain deeper insight into the nanostructuring of liquids.…”

Section: Discussionmentioning

confidence: 99%

Domain Analysis in Nanostructured Liquids: A Post‐Molecular Dynamics Study at the Example of Ionic Liquids

et al. 2015

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“…While non‐fluorinated ILs are known to form bulk nanostructures consisting of polar and nonpolar domains, fluorinated ILs typically exhibit additional nonpolar fluorous domains, in which the fluorinated chains preferentially agglomerate –. Alkylated and fluorinated chains can be present either in one single IL (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…alkyl chains in the cation and fluorinated chains in the anion or vice versa), or in IL mixtures with one IL containing alkyl chains and the other one containing fluorinated chains. Changing the relative chain length in one IL or the molar ratio of the two ILs in the mixture influences the related properties and the domain structure . It should be emphasized that using IL mixtures allows for fine‐tuning the properties in a very subtle way.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, investigations of the topmost layers of IL mixtures are getting more into the focus of research. A variety of studies has been performed, using reactive‐atom scattering with laser‐induced fluorescence detection (RAS‐LIF), neutron scattering, small‐angle X‐ray scattering and X‐ray reflectivity, time of flight secondary ion mass spectrometry (TOF‐SIMS), Rutherford backscattering spectroscopy (RBS), low‐energy ion scattering (LEIS), X‐ray photoelectron spectroscopy (XPS) and molecular dynamics (MD) simulations …”

Section: Introductionmentioning

confidence: 99%

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Temperature‐Dependent Surface Enrichment Effects in Binary Mixtures of Fluorinated and Non‐Fluorinated Ionic Liquids

Heller

Lexow

Greco

et al. 2020

Chemistry A European J

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Using angle-resolved X-ray photoelectron spectroscopy (ARXPS), we investigate the topmost nanometers of various binary ionic liquid (IL) mixtures at differentt emperatures in the liquid state. The mixtures consist of ILs with the same [PF 6 ] À anion but two different cations, namely 3methyl-1- (3,3,4,4,4-pentafluorobutyl)imidazoliumh exafluorophosphate, [PFBMIm][PF 6 ], and 1-butyl-3-methylimidazolium hexafluorophosphate, [C 4 C 1 Im][PF 6 ], with 10, 25, 50 and 75 mol %c ontento f[ PFBMIm][PF 6 ]. We observe ap referential enrichmento ft he fluorinated chain in the topmostl ayer, relative to the bulk composition, which is mostp ronounced for the lowest content of [PFBMIm][PF 6 ]. Upon cooling the mixtures stepwise from 95 8Cu ntil surfacec harging effects in XPS indicate solidification,w eo bserve ap ronouncedi ncreasei ns urfacee nrichmento ft he fluorinated chain with decreasing temperature in the liquid state. In contrast to the mixtures with lower[ PFBMIm] [PF 6 ]c ontents, cooling the 75 mol %m ixture additionallys hows an abrupt decrease of the fluorinated chain signal before complete solidification occurs, whichisa ssigned to partial precipitation effects.[a] B.

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Computational Spectroscopy of Ionic Liquids for Bulk Structure Elucidation

Saielli

2018

Advcd Theory and Sims

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Computational spectroscopy" refers to quantum chemistry protocols capable of predicting the electronic and/or magnetic spectra of molecules. The most common techniques used for structural assignment are infrared, electronic, and NMR spectroscopies. Chemists can normally deduce the chemical structure of an unknown substance by using a vast collection of empirical relationships linking the spectral features with the presence or absence of functional groups and, this part mostly by NMR, the connectivity between them and the relative stereochemistry. Computational spectroscopy is a powerful aid for structural elucidation when empirical relationships do not suffice to unambiguously assign the structure. In these cases, the calculated spectrum of a putative structure is compared with the experimental one and the match, or lack thereof, between the two, measured by several statistical parameters, indicates whether or not that structure is the correct one. Is it possible to extend such protocols to bulk phases of complex fluids, such as ionic liquids, rather than covalent molecules, in order to get insights into the average structure of the fluid? It is the aim of this Progress Report to highlight recent advances in this field through the discussion of specific case studies.

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Triphilic Ionic‐Liquid Mixtures: Fluorinated and Non‐fluorinated Aprotic Ionic‐Liquid Mixtures

Cited by 112 publications

References 65 publications

Domain Analysis in Nanostructured Liquids: A Post‐Molecular Dynamics Study at the Example of Ionic Liquids

Domain Analysis in Nanostructured Liquids: A Post‐Molecular Dynamics Study at the Example of Ionic Liquids

Temperature‐Dependent Surface Enrichment Effects in Binary Mixtures of Fluorinated and Non‐Fluorinated Ionic Liquids

Computational Spectroscopy of Ionic Liquids for Bulk Structure Elucidation

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