Hydrogen Bonding to π-Systems of Indole and 1-Methylindole:  Is There Any OH···Phenyl Bond?

Zhang, Ru Bo; Somers, Ken; Kryachko, Eugene S.; Nguyen, Minh Tho; Zeegers‐Huyskens, Th.; Ceulemans, Arnout

doi:10.1021/jp0525437

Cited by 33 publications

(39 citation statements)

References 41 publications

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“…The oxygen atom of this MI-TFE complex is further stabilised by hydrogen-bonding interaction with a second alcohol molecule, to give a ternary 1:2 complex. However, Ceulemans and coauthors [13] have discussed the validity of our theoretical calculations arguing, as other authors [14,15], that B3LYP density functional does not properly describe this kind of hydrogen bond. Ceulemans and coauthors [13] used the meta hybrid MPW1B95 density functional to demonstrate that MI-TFE p-complexation is not restricted to the pyrrole system, but it can also occur on the phenyl moiety of the indole ring with comparable interaction energies.…”

Section: Introductionmentioning

confidence: 72%

“…However, Ceulemans and coauthors [13] have discussed the validity of our theoretical calculations arguing, as other authors [14,15], that B3LYP density functional does not properly describe this kind of hydrogen bond. Ceulemans and coauthors [13] used the meta hybrid MPW1B95 density functional to demonstrate that MI-TFE p-complexation is not restricted to the pyrrole system, but it can also occur on the phenyl moiety of the indole ring with comparable interaction energies. Consequently, these authors re-interpreted our experimental data in terms of two separate 1:1 MI-TFE complexes with the alcohol OH group attached, respectively, to the pyrrolic and phenyl moieties of the MI ring.…”

Section: Introductionmentioning

confidence: 72%

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FTIR and fluorescence studies on the ground and excited state hydrogen-bonding interactions between 1-methylindole and water in water–triethylamine mixtures

Muñoz¹,

Carmona²,

Balón³

2007

Chemical Physics

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Section: Introductionmentioning

confidence: 72%

Section: Introductionmentioning

confidence: 72%

FTIR and fluorescence studies on the ground and excited state hydrogen-bonding interactions between 1-methylindole and water in water–triethylamine mixtures

Muñoz¹,

Carmona²,

Balón³

2007

Chemical Physics

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“…The groundstate hydrogen-bonded complexes of some related molecules, such as benzonitrile, [26,27] para-aminobenzonitrile, [28,29] DMABN, [30] and (methyl-)indole, [31] had previously been studied both experimentally and theoretically. Based upon these studies, we considered four complexes (visualized in Figure 9) for CMI.…”

Section: Ab Initio and Dft Calculations Of Hydrogen-bonded Complexes mentioning

confidence: 99%

“…It has been demonstrated that for weak hydrogen-bonded complexes, the MPW1B95 functional (modified Perdew and Wang exchange and Becke's 1995 correlation functional) provides results close to those of the more elaborate MP2 method, while the more recognized functionals, such as B3-LYP (Becke 3-parameter Lee-Yang-Parr exchange-correlation functional), [32,33] exhibit poor performance and may give qualitatively incorrect results. [31] To verify the performance of the MPW1B95 functional for the studied systems, the geometry of the collinear CN-H 2 O complex of CMI was optimized by MP2 with the 6-31 + + G** basis set. The deviation of DFT (with respect to MP2) for the …”

Section: Ab Initio and Dft Calculations Of Hydrogen-bonded Complexes mentioning

confidence: 99%

Efficient Singlet‐State Deactivation of Cyano‐Substituted Indolines in Protic Solvents via CNHO Hydrogen Bonds

et al. 2007

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The photophysical properties of indoline (I) and three of its derivatives, namely, N-methylindoline (MI), 5-cyanoindoline (CI), and 5-cyano-N-methylindoline (CMI), are studied in H-donating solvents of varying polarity. Based on measurements of fluorescence yield and lifetime, and of triplet yield and hydrated-electron formation, two distinct mechanisms of solvent-induced fluorescence quenching are evidenced. The first mechanism involves the cyano substituent and leads to an increase in the rate constant of internal conversion of one order of magnitude in ethanolic solution and of more than two orders of magnitude in water, as compared to solutions in n-hexane or acetonitrile. A similar trend had previously been observed in the case of 4-N,N-dimethylaminobenzonitrile (DMABN). The second mechanism reduces the fluorescence lifetimes of the non-cyanated derivatives in aqueous solution by one order of magnitude and is related to the formation of hydrated electrons. Neither of these mechanisms is influenced by methylation at the ring nitrogen. Quantum chemical calculations are performed on the ground and excited states of the hydrogen-bonded complexes between protic solvents and MI as well as CMI. Stable hydrogen-bonded configurations involving the CN substituent and a solvent OH group are found; these configurations are stable both in the ground and the first excited singlet states, whereas the corresponding complex at the ring amino nitrogen is stable in the ground state only. The CN--HO configuration is therefore a prime candidate for a mechanistic explanation of the observed quenching by the first mechanism. These findings may have useful applications for the design of fluorescence probes for water in biological systems.

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“…(2-propanol) complexes. The 2-propanol molecule has two rotational conformers, the structural forms of which have been theoretically studied in [12]. Figure 1e shows the calculated optimized equilibrium configuration of the carbazole complex with 2-propanol in the gauche conformation of the alcohol, and the experimentally recorded fluorescence excitation spectrum of carbazole complexes with a 2-propanol molecule.…”

Section: Carbazole-c 3 H 7 Oh (1-propanol) Complexesmentioning

confidence: 99%

Fluorescence excitation spectra of jet-cooled carbazole complexes with monohydric alcohols

et al. 2007

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We have analyzed the fluorescence excitation spectra of carbazole complexes with a single molecule of methyl, deuterated methyl, ethyl, and propyl (1-propanol and 2-propanol) alcohols, cooled in a supersonic jet. We have determined the shifts in the fluorescence excitation spectra of the complexes relative to the frequency of the purely electronic transition of unbound carbazole. They occur as a result of formation of hydrogen bonds between the N-H group of the carbazole and the OH group of the alcohols. The frequencies of stretching vibrations of the hydrogen bonds with different alcohols vary within the range 150-157 cm -1 , while the frequencies of the bending vibrations vary in the range 21-22.9 cm -1 . From the shape of the rotational contours of the bands for the purely electronic and vibronic transitions of the complexes, we determined that they belonged to rotational conformers. We calculated the equilibrium configurations of the complexes in the ground state.Introduction. Complexes formed as a result of hydrogen bonding in a supersonic jet have been studied in a state isolated from the surroundings, and have a controllable composition and a certain equilibrium configuration. Jet cooling of complexes down to a few kelvins ensures resolution of the vibrational structure in the vibronic spectra, which makes it possible to obtain information about the magnitudes of the shifts of the vibrational-rotational absorption and emission bands of the complexes relative to the spectra of the components and about the characteristic lowfrequency vibrations of the hydrogen bond, and to identify conformers of the complexes from the shape of their rotational contours. Carbazole complexes with various gas molecules have been studied to date [1][2][3][4][5].Carbazole complexes with monohydric saturated alcohols have not been studied. Making the alcohol molecule successively more complicated makes it possible to determine the magnitude of the shift in the spectra per methylene group. On the other hand, several rotational conformers of the complex may belong to a given isomer. In a number of cases, they can be identified from the shape of the rotational contours.Experimental Procedure and Calculations. The fluorescence excitation spectra were measured on the automatic spectrometric system described in [2]. The helium carrier gas at a pressure of 2 atm was passed over the surface of the alcohol, which was at a temperature of 233 K to 273 K; the mixture was fed to a prechamber heated to 423 K and containing saturated carbazole vapor. The pulsed supersonic jet was formed by discharge of the ternary gas mixture into the vacuum chamber through a circular nozzle of diameter 0.7 mm. The complexes, cooled down to a few kelvins, were excited perpendicular to the jet axis, at a distance of 19 mm from the nozzle, by the unfocused second-harmonic emission from a frequency-tunable dye laser pumped by the second harmonic of a neodymium-doped yttrium aluminum garnet laser. In recording the rotational contours of the bands, the spectral widt...

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Hydrogen Bonding to π-Systems of Indole and 1-Methylindole: Is There Any OH···Phenyl Bond?

Cited by 33 publications

References 41 publications

FTIR and fluorescence studies on the ground and excited state hydrogen-bonding interactions between 1-methylindole and water in water–triethylamine mixtures

FTIR and fluorescence studies on the ground and excited state hydrogen-bonding interactions between 1-methylindole and water in water–triethylamine mixtures

Efficient Singlet‐State Deactivation of Cyano‐Substituted Indolines in Protic Solvents via CNHO Hydrogen Bonds

Fluorescence excitation spectra of jet-cooled carbazole complexes with monohydric alcohols

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