Tracking “Apolar” NMe<sub>4</sub><sup>+</sup> Ions within Two Polyoxothiomolybdates that Have the Same Pores: Smaller Clathrate and Larger Highly Porous Clusters in Action

Korenev, Vladimir S.; Boulay, Antoine G.; Haouas, Mohamed; Bannani, Fatma; Fedin, Vladimir P.; Sokolov, Maxim N.; Terazzi, Emmanuel; Garai, Somenath; Müller, Achim; Taulèlle, Francis; Marrot, Jérôme; Leclerc, Nathalie; Floquet, Sébastien; Cadot, Emmanuel

doi:10.1002/chem.201303719

Cited by 14 publications

(20 citation statements)

References 73 publications

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“…Changing the nature of the pore from {Mo 9 O 9 } to {Mo 9 S 3 O 6 } leads to a drastic decrease of the stability constant from K S = 1550 ± 200 to 210 ± 20 while the main features of the capsule (ionic charge, size and shape) remain almost unchanged. 19 The rationale of such a result is the larger ionic radius of the sulfur atom which reduced the inner space of the pore and then increases the unfavorable steric effect for the NMe 4 + plugging. We tried to get Xray diffraction structural data to support these solution studies.…”

Section: Resultsmentioning

confidence: 99%

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

et al. 2015

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ABSTRACT:The effectiveness of the interactions between various alkyl ammonium cations and the well-defined spherical Keplerate-type {Mo 132 } capsule has been tracked by 1 H DOSY NMR methodology which reveals a strong dependence of the selfdiffusion coefficient of the cationic guests balancing from the solvated to the plugging situations. Analysis of the data is fully consistent with a two-site exchange regime involving the 20 independent {Mo 9 O 9 } receptors of the capsule. Furthermore, quantitative analysis allowed determining the stability constants associated to the plugging process of the pores. Surprisingly, the affinity of the capsule for a series of cationic guests increases continuously with its apolar character as shown by the significant change of the stability constant from 370 to 6500 from NH 4 + and NEt 4 + , respectively. Such observations, supported by the thermodynamic parameters evidence that the major factor dictating selectivity in the trapping process is mainly the so-called "hydrophobic effect". Computational studies, using molecular dynamics simulations have been carried out in the conjunction of the experimental data. The analysis of the radial distribution functions g(r) reveals that NH 4 + and NMe 4 + ions behave differently in the vicinity of the capsule. The NH 4 + ions do not exhibit well-defined distributions in its close vicinity. In contrast, the NMe 4 + ions were identified as sharp distributions related to different scenario such as firmly trapped or as labile guest facing the {Mo 9 O 9 } pores. These conjugated experimental and theoretical insights should aid the exploitation of these giant polyoxometalates in solution for various applications.

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Section: Resultsmentioning

confidence: 99%

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

et al. 2015

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“…Such an observation has been fully analyzed from an experimental and theoretical point of views in a recent report which demonstrates that specific interactions between the capsules and DMA + cations take place involving the twenty {Mo 6 O 9 } ether crown‐like pores of the capsule 30. Such specific interactions have been observed also in solution between the NMe 4 + ion and the sulfurated Keplerate [Mo 132 O 312 S 60 (H 2 O) 72 (CH 3 COO) 30 ] 42− 31. Such solution studies and related results correspond to complementary insights previously evidenced in the solid state and described as the pore plugging process 32…”

Section: Resultsmentioning

confidence: 99%

Tunable Keplerate Type‐Cluster “Mo₁₃₂” Cavity with Dicarboxylate Anions

Lai

Awada

Floquet

et al. 2015

Chemistry A European J

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The internal functionalization of the Keplerate-type capsule Mo132 has been carried out by ligand exchange leading to the formation of glutarate and succinate containing species isolated as ammonium or dimethylammonium salts. Solution NMR analysis is consistent with asymmetric inner dicarboxylate ions containing one carboxylato group grafted onto the inner side of the spheroidal inorganic shell while the second hangs toward the center of the cavity. Such a disposition has been confirmed by the single-crystal X-ray diffraction analysis of the glutarate containing {Mo132 } species. A detailed NMR solution study of the ligand-exchange process allowed determining the binding constant KL of acetate (AcO(-) ), succinate (HSucc(-) ) or glutarate (HGlu(-) ) ligands at the 30 inner coordinating sites, which vary such as K AcO -

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“…[83] In this case, the alkyl chain length is probably too small to get liquid crystals phase but they used it to prepare coassembly of spherical 6.2 nm maghemite (- ligands and higher charge. [33] The larger charge of the capsule allows associating more [82,84] with the permission from the Royal Society of Chemistry) 33represents an attractive system. [85] It possesses a large anionic pocket of about 1 nm in diameter, which is able to include various transition metals, a key step for the elaboration of efficient materials for magnetic, luminescent, catalytic or electrocatalytic properties.…”

Section: Pairing Poms With Non-mesogenic Cationsmentioning

confidence: 99%

“…The Linqvist structure [M 6 O 19 ] xand its derivatives (Figure 1) are probably the main archetypical structure of this class but in the domain of isopolyoxomolybdates, Müller et al opened a new field of investigation when they reported the discovery of a fullerene-like, all-inorganic hollow spheres containing 132 molybdenum centers in 1998 (Figure 1). [30] [21,[31][32][33] Not only aesthetic, these nanometric hollow clusters behave as functional nanoflasks for cations or molecules trapping, [34][35][36][37] catalysis [38] or specific chemical transformations. [39] This family of polyoxomolybdates was also complemented by other giant POMs namely the "big wheels" {Mo-154}, {Mo-176} and {Mo-248}, and the "blue lemon" {Mo-368}, which expanded the frontiers of inorganic chemistry to the mesoscopic world (see Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Designing Functional Polyoxometalate‐Based Ionic Liquid Crystals and Ionic Liquids

et al. 2019

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Polyoxometalate (POM) compounds constitute a wide family rich of more than several thousand inorganic compounds which can be finely tuned at the molecular level. Considering their high diversities in structures and properties, the incorporation of such inorganic components into liquid crystalline phases or ionic liquid phases is particularly relevant for the elaboration of functional materials. By adjusting the molecular structures of the anions and the nature of the counter cations, many authors designed different types of mesophases sometimes with application in optoelectronics, or true POM-based Ionic liquids (POM-ILs with melting temperature below 100 °C). The latter turn out to be highly interesting for various applications in catalysis, depollution, or protection of the historical heritage. This review focuses on the recent developments in these organic/inorganic hybrid materials, POMbased Ionic liquid crystal and POM-ILs and their applications.

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Tracking “Apolar” NMe₄⁺ Ions within Two Polyoxothiomolybdates that Have the Same Pores: Smaller Clathrate and Larger Highly Porous Clusters in Action

Cited by 14 publications

References 73 publications

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

Tunable Keplerate Type‐Cluster “Mo₁₃₂” Cavity with Dicarboxylate Anions

Designing Functional Polyoxometalate‐Based Ionic Liquid Crystals and Ionic Liquids

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Tracking “Apolar” NMe4+ Ions within Two Polyoxothiomolybdates that Have the Same Pores: Smaller Clathrate and Larger Highly Porous Clusters in Action

Cited by 14 publications

References 73 publications

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

Hydrophobic Effect as a Driving Force for Host–Guest Chemistry of a Multi-Receptor Keplerate-Type Capsule

Tunable Keplerate Type‐Cluster “Mo132” Cavity with Dicarboxylate Anions

Designing Functional Polyoxometalate‐Based Ionic Liquid Crystals and Ionic Liquids

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Tracking “Apolar” NMe₄⁺ Ions within Two Polyoxothiomolybdates that Have the Same Pores: Smaller Clathrate and Larger Highly Porous Clusters in Action

Tunable Keplerate Type‐Cluster “Mo₁₃₂” Cavity with Dicarboxylate Anions