Control over the Self-Assembly and Dynamics of Metallacarborane Nanorotors by the Nature of the Polymer Matrix: A Solid-State NMR Study

Brus, Jiřı́; Zhigunov, Alexander; Czernek, Jiřı́; Kobera, Libor; Uchman, Mariusz; Matějíček, Pavel

doi:10.1021/ma501117a

Cited by 34 publications

(46 citation statements)

References 73 publications

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“…[35] Surprisingly, no aggregates form in the PEO-complex, where the clusters are evenly dispersed within the PEO-matrix. [35] Thus, the aggregation is probably controlled by the mutual COSAN-matrix interaction.…”

Section: Resultsmentioning

confidence: 99%

Nonclassical Hydrophobic Effect in Micellization: Molecular Arrangement of Non‐Amphiphilic Structures

Uchman

Abrikosov

Lepšı́k

et al. 2017

Advcd Theory and Sims

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Micellization brought about by nonclassical hydrophobic effect invokes enthalpy as the driving force. Thus, the underlying molecular phenomena differ from the entropically dominated hydrophobic effect. In quest for a molecular-scale understanding, we report on the molecular arrangement of nonamphiphilic structures of an anionic boron cluster compound, COSAN. We synergistically combine experimental (NMR and calorimetry) and theoretical (molecular dynamics and quantum chemical calculations) approaches. The experimental data support the mechanism of closed association of COSAN, where the self-assembly is driven by the enthalpy contribution to the free energy. Molecular dynamics simulations in explicit solvent show that water molecules form a patchy network around COSAN molecules, giving rise to the strong hydrophobic self-association. In the second solvation shell, water forms a slightly hydrophilic "spot" close to the C-H segments of the cluster.

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Section: Resultsmentioning

confidence: 99%

Nonclassical Hydrophobic Effect in Micellization: Molecular Arrangement of Non‐Amphiphilic Structures

Uchman

Abrikosov

Lepšı́k

et al. 2017

Advcd Theory and Sims

Self Cite

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“…120 The feasibility and performance of several possible rotors have been investigated in molecular dynamics studies, including polyhedral CB 11 , C 2 B 8 , or supra-icosahedral CB 13 or C 2 B 12 clusters that have [n]staffane "axles" and condensed aromatic ring "blades" and are mounted on a square grid and driven by flowing gas or an electric field. 117 Solid-state NMR spectra show that the metallacarborane anions rotate relatively freely in a rigid polymer matrix. 21(b) illustrates one such system containing a CB 11 cluster.…”

Section: Rotorsmentioning

confidence: 99%

Carboranes in the chemist's toolbox

2015

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Once seldom encountered outside of a few laboratories, carboranes are now everywhere, playing a role in the development of a broad range of technologies encompassing organic synthesis, radionuclide handling, drug design, heat-resistant polymers, cancer therapy, nanomaterials, catalysis, metal-organic frameworks, molecular machines, batteries, electronic devices, and more. This perspective highlights selected examples in which the special attributes of carboranes and metallacarboranes are being exploited for targeted purposes in the laboratory and in the wider world.

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“…[3,19,20] Thee ffect becomes particularly pronounced for superchaotropic ions that reach beyond the classical Hofmeister scale. [10,18] Thechaotropic effect extends to molecular recognition events with macrocyclic hosts, [10,12,[21][22][23][24][25][26][27] biologically relevant interactions with proteins and peptides, [13,[28][29][30][31][32] association to small organic molecules, [10,33] binding to membranes, [17,[34][35][36][37][38] polymers, [39] as well as colloids, [15,18,40] and it manifests itself in solid-state structures between superchaotropic ions and organic components. [10,12,26,41,42] Thet erms "chaotropic effect" and "superchaotropic ions" have been readily absorbed by the chemical literature in different contexts.…”

Section: Introductionmentioning

confidence: 99%

The Chaotropic Effect as an Assembly Motif in Chemistry

2018

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Following up on scattered reports on interactions of conventional chaotropic ions (for example, I−, SCN−, ClO4 −) with macrocyclic host molecules, biomolecules, and hydrophobic neutral surfaces in aqueous solution, the chaotropic effect has recently emerged as a generic driving force for supramolecular assembly, orthogonal to the hydrophobic effect. The chaotropic effect becomes most effective for very large ions that extend beyond the classical Hofmeister scale and that can be referred to as superchaotropic ions (for example, borate clusters and polyoxometalates). In this Minireview, we present a continuous scale of water–solute interactions that includes the solvation of kosmotropic, chaotropic, and hydrophobic solutes, as well as the creation of void space (cavitation). Recent examples for the association of chaotropic anions to hydrophobic synthetic and biological binding sites, lipid bilayers, and surfaces are discussed.

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Control over the Self-Assembly and Dynamics of Metallacarborane Nanorotors by the Nature of the Polymer Matrix: A Solid-State NMR Study

Cited by 34 publications

References 73 publications

Nonclassical Hydrophobic Effect in Micellization: Molecular Arrangement of Non‐Amphiphilic Structures

Nonclassical Hydrophobic Effect in Micellization: Molecular Arrangement of Non‐Amphiphilic Structures

Carboranes in the chemist's toolbox

The Chaotropic Effect as an Assembly Motif in Chemistry

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