Synthesis and structures of crystalline solvates formed of pyridinium N-phenoxide (Reichardt's-type) betaine dyes and alcohols

Kurjatschij, Sandra; Seichter, Wilhelm; Weber, Edwin

doi:10.1039/b9nj00540d

Cited by 17 publications

(10 citation statements)

References 53 publications

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“…The twisting between these rings prevents full π-conjugation, rendering 1 as zwitterionic neutral molecules with a large dipole moment. The interplanar angle of 1a was determined to 55° by X-ray diffraction analysis. , However, the charge-transfer process is generally not affected by coplanarity because both the unhindered betaine 1b and the nearly orthogonal ortho isomer of 1a show remarkable solvatochromic properties. , The phenolate unit of 1 is highly basic, capable of interacting as hydrogen bond acceptor with hydrogen bond donor (HBD) solvents and Lewis acids. In contrast, interactions of 1 with Lewis bases are weak due to the delocalization of the positive charge in the pyridinium ring.…”

Section: Introductionmentioning

confidence: 99%

“…The interplanar angle of 1a was determined to 55°by X-ray diffraction analysis. 14,15 However, the charge-transfer process is generally not affected by coplanarity because both the unhindered betaine 1b and the nearly orthogonal ortho isomer of 1a show remarkable solvatochromic properties. 16,17 The phenolate unit of 1 is highly basic, capable of interacting as hydrogen bond acceptor with hydrogen bond donor (HBD) solvents and Lewis acids.…”

Section: ■ Introductionmentioning

confidence: 99%

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Micro- vs Macrosolvation in Reichardt’s Dyes

2021

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Solvation is a complex phenomenon involving electrostatic and van der Waals forces as well as chemically more specific effects such as hydrogen bonding. To disentangle global solvent effects (macrosolvation) from local solvent effects (microsolvation), we studied the UV−vis and IR spectra of a solvatochromic pyridinium-N-phenolate dye (a derivative of Reichardt's dye) in rare gas matrices, in mixtures of argon and water, and in water ice. The π−π* transition of the betaine dye in the visible region and its C−O stretching vibration in the IR region are highly sensitive to solvent effects. By annealing argon matrices of the betaine dye doped with low concentrations of water, we were able to synthesize 1:1 water−dye complexes. Formation of hydrogen-bonded complexes leads to small shifts of the π−π* transition only, as long as the global polarity of the matrix environment does not change. In contrast, changes of the global polarity result in large spectral band shifts. Hydrogen-bonded complexes of the betaine dye are more sensitive to global polarity changes than the dye itself, explaining why E T values determined with Reichardt's dyes are very different for protic and nonprotic solvents, even if the relative permittivities of these solvents are similar.

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Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Micro- vs Macrosolvation in Reichardt’s Dyes

2021

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“…7,11 However, reports on the solid-state behaviour of 1 are rare. [12][13][14] The high solubility of 1 in a wide range of solvents makes it ideal for investigating the influence of crystallisation solvent on packing in the solid state. The only crystal structures of 1 that have been reported to date are the solvates of ethanol and iso-propanol, which are isostructural.…”

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confidence: 99%

“…The only crystal structures of 1 that have been reported to date are the solvates of ethanol and iso-propanol, which are isostructural. 12 Crystal structures of the protonated form of Reichardt's dye have also been obtained by crystallisation in the presence of nitric and sulphuric acid. 14 Here, we report a systematic study of solvatomorphism of 1 based on crystallisation experiments in a wide range of different solvent systems.…”

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confidence: 99%

Solvatomorphism of Reichardt's dye

2018

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“…Surveying the literature reveals many papers that describe the properties of this dye, [3][4][5][6][7][8][9] but only a few describe the 1 H data [10][11][12][13] and 13 C NMR assignments 10 in any detail. Much to our surprise, some of the critical chemical shift values we observed were significantly different from those previously reported.…”

Section: Introductionmentioning

confidence: 99%

Reichardt’s dye: the NMR story of the solvatochromic betaine dye

2014

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Reichardt's dye, 2,6-diphenyl-4-(2,4,6-triphenyl-1-pyridinio)phenolate (1), has a very large negative solvatochromism in the long wavelength absorption in the UV-vis spectrum when going from nonpolar to polar solvents. This shift provides the basis of the important and widely used E T (30) scale of solvent polarity. While many papers have investigated the properties of this dye, only a few describe the 1 H and 13 C NMR assignments in any detail. We report herein, our detailed analysis of the proton and carbon chemical shift assignments for this molecule based on 1D and 2D NMR measurements, as well as those of the protonated and methoxy derivatives 2 and 3, respectively. Much to our surprise, some of the critical chemical shift values we observed were significantly different from those previously reported. In addition, we discovered a good correlation not only between the solvent polarity and the chemical shifts of carbons C1 and C4 of Reichardt's dye (1), but also between the concentration of the dye and these chemical shifts.Résumé : Le colorant de Reichardt, 2,6-diphenyl-4-(2,4,6-triphenyl-1-pyridinio)phenolate (1), présente un solvatochromisme négatif très élevé dans les grandes longueurs d'onde du spectre d'absorption ultraviolet-visible lorsqu'on passe de solvants apolaires à des solvants polaires. C'est sur cette variation que se fonde l'échelle E T (30) de polarité des solvants, qui est importante est largement utilisée. Même si de nombreuses études se sont penchées sur les propriétés de ce colorant, peu ont décrit en détail les attributions des spectres des RMN 1 H et 13 C. Nous décrivons dans le présent article notre analyse approfondie des déplacements chimiques des protons et carbones de cette molécule à l'aide des mesures des RMN 1D et 2D et de ceux des dérivés protonés et méthoxy, respectivement 2 et 3. À notre plus grande surprise, certaines des principales valeurs de déplacement chimique observées sont très différentes de celles relevées précédemment. De plus, nous avons découvert une corrélation claire, non seulement entre la polarité et les déplacements chimiques des carbones C1 et C4 du colorant de Reichardt (1), mais aussi entre la concentration du colorant et ces déplacements chimiques. [Traduit par la Rédaction] Mots-clés : colorant de Reichardt, solvatochromisme, déplacements chimiques en RMN, effet de solvant.

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Synthesis and structures of crystalline solvates formed of pyridinium N-phenoxide (Reichardt's-type) betaine dyes and alcohols

Cited by 17 publications

References 53 publications

Micro- vs Macrosolvation in Reichardt’s Dyes

Micro- vs Macrosolvation in Reichardt’s Dyes

Solvatomorphism of Reichardt's dye

Reichardt’s dye: the NMR story of the solvatochromic betaine dye

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