Surface Activity and Molecular Organization of Metallacarboranes at the Air–Water Interface Revealed by Nonlinear Optics

Gassin, Pierre-Marie; Girard, Luc; Martin-Gassin, Gaëlle; Brusselle, Damien; Jonchère, Alban; Diat, Olivier; Viñas, Clara; Teixidor, Francesc; Bauduin, Pierre

doi:10.1021/acs.langmuir.5b00125

Cited by 38 publications

(44 citation statements)

References 44 publications

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“…[16][17][18][19][20][21][22][23][24] Mechanism of formation of small aggregates (sometimes called "micelles") 20 has been already extensively studied, and it obeys the closed association model with critical aggregation concentration, CAC. 23 To reveal a mechanism of the aggregation, NMR spectroscopy is a suitable method.…”

Section: Resultsmentioning

confidence: 99%

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

et al. 2016

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This is the first experimental evidence that both self-assembly and surface activity are common features of all water-soluble boron cluster compounds. The solution behavior of anionic polyhedral boranes (sodium decaborate, sodium dodecaborate, and sodium mercaptododecaborate), carboranes (potassium 1-carba-dodecaborate), and metallacarboranes {sodium [cobalt bis(1,2-dicarbollide)]} was extensively studied, and it is evident that all the anionic boron clusters form multimolecular aggregates in water. However, the mechanism of aggregation is dependent on size and polarity. The series of studied clusters spans from a small hydrophilic decaborate-resembling hydrotrope to a bulky hydrophobic cobalt bis(dicarbollide) behaving like a classical surfactant. Despite their pristine structure resembling Platonic solids, the nature of anionic boron cluster compounds is inherently amphiphilic-they are stealth amphiphiles.

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Section: Resultsmentioning

confidence: 99%

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

et al. 2016

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“…It should be noted that nano‐ions with the lowest charge densities, that is, with a more pronounced hydrophobic character, display some tendency to self‐assemble in water, for example, the Keggin‐type phosphotungstate, PW 12 O 40 3− , some giant POMs such as the ones from the Keplerate type, and halogenated dodecaborates . Among nano‐ions and boron clusters, metallabisdicarbollides stand out, as they exhibit the properties of surfactants: self‐assembly in water, surface activity, foaming, and formation of lyotropic phases presumably by combining high hydrophobicity, molecular polarity (or anisotropic distribution of charge), and intramolecular di‐H‐bond formation. Additionally, hydrophobic (organic) ions such as tetraphenylborate have also been termed superchaotropes regarding their tendency to adsorb to hydrophobic interfaces…”

Section: Figurementioning

confidence: 99%

How Nano‐Ions Act Like Ionic Surfactants

Hohenschutz,

Grillo,

Diat

et al. 2020

Angew Chem Int Ed

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Recently, nanometric ions were shown to adsorb to hydrated neutral surfaces and to bind to the cavities of macrocyclic molecules with an unexpectedly strong affinity arising from a solvent‐mediated effect named superchaotropicity. We show here that nano‐ions at low concentrations (μm range), similarly to anionic surfactants, induce the spontaneous transformation of a swollen lyotropic lamellar phase of non‐ionic surfactant into a vesicle phase. This transition occurs when the neutral lamellae acquire charges, either by adsorption of the nano‐ions onto, or by anchoring of the ionic surfactant into the lamellae. In contrast to ionic surfactants, nano‐ions strongly dehydrate the neutral surfactant assemblies. As a conclusion, these purely inorganic nanometric ions act as alternatives to the widely used organic ionic surfactants.

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“…[59][60][61][62][63] This bonding can be interpreted in terms of individual bond description and the molecular electrostatic potential distribution [64] (ESP, Figure 5, a). It can be seen that the ESP is negative in the apical region of carborane and above the phenyl rings, and positive in the region of H(C) atoms; the ESP distribution in the region of two dicarbollide anions is different.…”

Section: Esp Distribution and Dihydrogen Bondingmentioning

confidence: 99%

Studies of Multicenter and Intermolecular Dihydrogen B–H···H–C Bonding in [4,8,8′‐exo‐{PPh₃Cu}‐4,8,8′‐(μ‐H)₃‐commo‐3,3′‐Co(1,2‐C₂B₉H₉)(1′,2′‐C₂B₉H₁₀)]

et al. 2015

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The development of new conjugated organic materials for dyes, sensors, imaging, and flexible light emitting diodes, field‐effect transistors, and photovoltaics has largely relied upon assembling π‐conjugated molecules and polymers from a limited number of building blocks. The use of the dithiolodithiole heterocycle as a conjugated building block for organic materials is described. The resulting materials exhibit complimentary properties to widely used thiophene analogues, such as stronger donor characteristics, high crystallinity, and a decreased HOMO–LUMO gap. The dithiolodithiole (C4S4) motif is readily synthetically accessible using catalytic processes, and both the molecular and bulk properties of materials based on this building block can be tuned by judicious choice of substituents.

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Surface Activity and Molecular Organization of Metallacarboranes at the Air–Water Interface Revealed by Nonlinear Optics

Cited by 38 publications

References 44 publications

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

How Nano‐Ions Act Like Ionic Surfactants

Studies of Multicenter and Intermolecular Dihydrogen B–H···H–C Bonding in [4,8,8′‐exo‐{PPh₃Cu}‐4,8,8′‐(μ‐H)₃‐commo‐3,3′‐Co(1,2‐C₂B₉H₉)(1′,2′‐C₂B₉H₁₀)]

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Surface Activity and Molecular Organization of Metallacarboranes at the Air–Water Interface Revealed by Nonlinear Optics

Cited by 38 publications

References 44 publications

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

Stealth Amphiphiles: Self-Assembly of Polyhedral Boron Clusters

How Nano‐Ions Act Like Ionic Surfactants

Studies of Multicenter and Intermolecular Dihydrogen B–H···H–C Bonding in [4,8,8′‐exo‐{PPh3Cu}‐4,8,8′‐(μ‐H)3‐commo‐3,3′‐Co(1,2‐C2B9H9)(1′,2′‐C2B9H10)]

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Studies of Multicenter and Intermolecular Dihydrogen B–H···H–C Bonding in [4,8,8′‐exo‐{PPh₃Cu}‐4,8,8′‐(μ‐H)₃‐commo‐3,3′‐Co(1,2‐C₂B₉H₉)(1′,2′‐C₂B₉H₁₀)]