Intramolecular and intermolecular hydrogen bonds in aminophenols

IR-Fourier spectroscopy methods are adopted to study intramolecular and intermolecular hydrogen bonds that form in CCl₄ solutions of aminophenol derivatives and in a solid phase of these compounds pressed in KBr. If a hydroxyl group is present in the molecule in the ortho-position to an amino group, then intramolecular interactions between OH and NH groups will take place in aminophenol solutions. Intramolecular O–H⋅⋅⋅O=S=O and N–H⋅⋅⋅O=S=O hydrogen bonds are found in solutions of compounds containing a sulfonamide fragment. Additional acylation of the amino group causes an intramolecular O–H⋅⋅⋅O=C hydrogen bond to form in solutions. Functional groups OH, NH, SO₂, and C=O interact with one another in various ways in the solid phase to form intermolecular hydrogen bonds in aminophenols.     

Intramolecular hydrogen bonds and antioxidant activity of aminophenols

We have used IR Fourier spectroscopy to study intramolecular interactions in solutions of aminophenols in n-hexane. When the hydroxyl group in the molecule is ortho to the amino group, O-H⋯N and N-H⋯O intramolecular hydrogen bonds are formed in the aminophenols. Adding two tert-butyl groups to the benzene ring of ortho-aminophenols strengthens the O-H⋯N bond in the molecules, and prevents formation of an N-H⋯O bond. Additional acylation of the amino group in ortho-aminophenols leads to formation of an O-H⋯O=C intramolecular hydrogen bond. Formation of the above-indicated intramolecular hydrogen bonds in aminophenols affects the course of radiation-induced reactions occurring in n-hexane with participation of these compounds. The antioxidant properties of the aminophenols are enhanced when the hydroxyl groups in the molecules are found in the free state, and are diminished when strong O-H⋯N or O-H⋯O=C intramolecular hydrogen bonds are formed. __________ Translated from Zhurnal Prikladnoi Spektroskopii, Vol. 74, No. 5, pp. 577–582, September–October, 2007.     

Intramolecular hydrogen bonds in the phenylazomethine biomolecules

The FTIR spectra of the solutions of biologically active molecules (screened phenylazomethines) in CCl₄ are studied. The role of the OH- and N=C groups in the formation of the intramolecular H bonds is analyzed. The analysis of the FTIR spectra shows that three types of H bonds (O-H…O-H, O-H…N=C, and O-H…O-H…N=C) are possible in the molecules under study. A correlation of the H-bond formation in the phenylazomethine molecules and the antivirus properties of such molecules is revealed. The antivirus activity is observed for molecules that exhibit intramolecular O-H…O-H…N=C bonds in the absence of free hydroxyls. The antivirus activity decreases when the molecule contains additional OH groups that are not involved in H bonds.     

Manifestation of intramolecular hydrogen bonds in the IR spectra of bioactive aminophenols

The intermolecular interactions in solutions of aminophenols in CCl₄ are studied by the methods of IR Fourier spectroscopy. If the hydroxyl groups of aminophenol molecules occupy the ortho positions with respect to the amino groups of the molecules, the hydroxyl and amino groups are involved in intramolecular interactions with the formation of hydrogen bonds O-H...N and N-H...O. The introduction of two additional tert-butyl groups into the structure of the aminophenol molecule facilitates the formation of O-H...N bonds and impedes the formation of N-H...O bonds. The occurrence of the carbonyl group in the structure of aminophenols leads to the formation of intramolecular hydrogen bonds O-H...O=C. The introduction of the methyl groups into carbonyl-containing aminophenols transforms the O-H...O=C bond into the hydrogen bond N-H...O=C.     

Intramolecular hydrogen bonds in compounds of porphin type

NH modes are examined for porphins and simpler compounds. The NH frequency is found to vary smoothly in the sequence pyrrole to phihalocyanin, which cannot be explained in terms of an intramolecular hydrogen bond. The effects are ascribed to conjugation and formation of a macro ring.     

Hydrogen bonds of anti-HIV active aminophenols

Analysis of IR-Fourier spectra from solutions and crystals of antiviral sulfo-containing aminophenols has shown that various types of intramolecular and intermolecular interactions can occur in molecules of these compounds. Three types of intramolecular hydrogen bonds (O–H⋅⋅⋅N, O–H⋅⋅⋅O=S=O, and N–H⋅⋅⋅O=S=O) are formed in CCl₄ solutions of the sulfo-containing aminophenols. The formation of intermolecular H-bonds involving the NH- and OH-groups and the preservation of the intramolecular O–H⋅⋅⋅O=S=O H-bond are characteristic of the anti-HIV active aminophenol crystals. Spectral attributes are determined in order to distinguish between the anti-HIV active and inactive sulfo-containing aminophenols.     

Symmetric hydrogen bonds in ice X

Raman measurements on Ice VIII under pressures up to 50 GPa reveal strong line shifts, changes in isotope frequency ratio, intensity decreases, and the appearance of one new line around 38 GPa. These observations are consistent with the formation of symmetric hydrogen bonds and a new phase, Ice X, with cuprit structure.     

Correlations among hydrogen bonds in liquid water

By performing computer simulations of water with the TIP5P potential we show that structures formed by two or more hydrogen bonds affect the dynamical and static properties of water, especially in the vicinity of freezing temperature. In particular, the short time correlation between two coupled hydrogen bonds cannot be predicted assuming the statistical independence of the single hydrogen bonds. This introduces an additional relaxation time of approximately 9 ps close to the freezing point. We also find that the time persistence of structures formed by several hydrogen bonds (the first solvation shell) correlates with the local density, which is smaller around water molecules with a long-living environment.     

Oxygen nonstoichiometry and hydrogen bonds in BaTiO3

The origin of hydroxyl in the lattice of barium titanate as a consequence of the reaction of hydrogen with oxygen ions in the lattice is described. A band at the wave number 1770 cm^?1 was assigned to this hydroxyl in the infra-red spectrum. The samples were annealed in a stream of hydrogen and in sealed ampoules containing hydrogen or deuterium at temperatures above 900°C, and at 50 to 500° C when hydrogen plasma was used. The defect structure of the sample after prolonged annealing in hydrogen is discussed.     

Characterization of blue-shifting hydrogen bonds in small complexes

ABSTRACT

The so-called improper blue-shifting (BS) Hydrogen bond, characterising some small complexes, is theoretically investigated by first-principles calculations based on the Density Functional Theory. We compute structural, energetic, electronic and electrostatic properties not only of complexes with linear Hydrogen bonds but also of systems with multiple intermolecular contacts leading to the formation of ‘bifurcated’ or even ‘trifurcated’ Hydrogen bonds. In particular, Hydrogen bonds are characterised in terms of differential electron densities distributions and profiles, and of the shifts of the centres of Maximally localised Wannier Functions. The information from the latter quantities can be conveyed into simple geometric bonding parameters that are helpful in characterising the interatomic bonds. The effect of including dispersion corrections for describing BS Hydrogen bonds is also investigated. Our detailed comparison of the properties of systems with BS Hydrogen bonds to those of others, where more conventional red-shifting Hydrogen bonds are formed, supports the view that there is no fundamental difference between the two kinds of bonds.     

Ultrafast multidimensional dynamics of strong hydrogen bonds

The laser driven dynamics of the OH(D) stretching vibration in phthalic acid monomethylester is investigated. The combination of a 55-dimensional all-Cartesian reaction surface Hamiltonian and the time-dependent self-consistent field approach is shown to provide a microscopic picture of intramolecular vibrational energy redistribution taking place upon interaction with an external laser field. Choosing suitable zeroth-order vibrational states and combinations thereof a quasi-periodic in-phase and out-of-phase oscillatory behavior is observed manifesting energy flow on different time scales. The fingerprints of this behavior in transient absorption spectroscopy are also discussed. Received 24 August 2000 and Received in final form 11 October 2000     

Ferroelectric order of parallel bistable hydrogen bonds

A new NH.N hydrogen-bonded ferroelectric crystal of [C6H12N2H]+ReO - 4 (dabcoHReO4) exhibits exceptional dielectric properties that result from the unique structure where all the bistable NH...N hydrogen bonds are parallel and directed exactly in the same sense. Consequently, the main structural origin of the spontaneous polarization of the crystal is the identical orientation of the asymmetric NH+...N hydrogen bonds along [001]. This first observation of a ferroelectric with parallel arrangement of the NH+...N bonded aggregates, gives temperature-independent and the highest spontaneous polarization ever reported for an organic or water-soluble substance.