Dynamics of Crystalline <i>N</i>-Methylacetamide:  Temperature Dependence of Infrared and Inelastic Neutron Scattering Spectra

Barthes, Mariette; Bordallo, H. N.; Eckert, Juergen; Maurus, Olivier; Nunzio, and Giorgio de; León, J.

doi:10.1021/jp981743y

Cited by 21 publications

(26 citation statements)

References 17 publications

(47 reference statements)

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“…Interestingly, in both forms, the temperature evolution of the intensity ( I ) of these modes follows an exponential decay of the form I ∝ 1 − e − W / k normalB T This corroborates well with our zero-point periodic calculations and the experimental IINS data from FDS for form I that demonstrate that these bands are assigned to methyl librational modes mixed with collective vibrations (which are dependent on thermal energy). Similar librations were evidenced in N -methylacetamide in the early studies of paracetamol and acetanilide and in phenacetin . For form II, however, our computational results show that the methyl librational modes are mixed with phenyl ring rotations.…”

Section: Resultssupporting

confidence: 82%

“…In the inset of Figure 2a,b, the modes located at approximately 95 and 100 meV for the monoclinic form and at 105 and 120 meV for the orthorhombic form can be assigned to the out-ofplane bending of the N−H amide group. 40 These bands also contain O−H and N−H bending modes, highlighting differences in the strength and symmetry of the hydrogen bonding of the donor −NH and −OH groups. The most striking finding in this spectral region is that the −OH bend modes occur at a much higher energy in form II (+8 meV).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Polymorphism of Paracetamol: A New Understanding of Molecular Flexibility through Local Methyl Dynamics

et al. 2014

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This study focuses on the interplay of molecular flexibility and hydrogen bonding manifested in the monoclinic (form I) and orthorhombic (form II) polymorphs of paracetamol. By means of incoherent inelastic neutron scattering and density functional theory calculations, the relaxation processes related to the methyl side-group reorientation were analyzed in detail. Our computational study demonstrates the importance of considering quantum effects to explain how methyl reorientations and subtle conformational changes of the molecule are intertwined. Indeed, by analyzing the quasi elastic signal of the neutron data, we were able to show a unique and complex motional flexibility in form II, reflected by a coupling between the methyl and the phenyl reorientation. This is associated with a higher energy barrier of the methyl rotation and a lower Gibbs free energy when compared to form I. We put forward the idea that correlating solubility and molecular flexibility, through the relation between pKa and methyl rotation activation energy, might bring new insights to understanding and predicting drug bioavailability.

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Section: Resultssupporting

confidence: 82%

Section: ■ Results and Discussionmentioning

confidence: 99%

Polymorphism of Paracetamol: A New Understanding of Molecular Flexibility through Local Methyl Dynamics

et al. 2014

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“…This splitting has been observed before and is of unclear origin. [30][31][32] In ACN the NH main peak at 3295 cm −1 is observed both in the parallel and perpendicular measurements, however, with a relative shift of 11 cm −1 [ Fig. 2(a)].…”

Section: A Absorption Spectra Of the Nh And The C B O Bandsmentioning

confidence: 99%

Spectral response of crystalline acetanilide andN-methylacetamide: Vibrational self-trapping in hydrogen-bonded crystals

Edler

Hamm

2004

Phys. Rev. B

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Femtosecond pump-probe and Fourier transform infrared spectroscopy is applied to compare the spectral response of the amide I band and the NH-stretching band of acetanilide (ACN) and N-methylacetamide (NMA), as well as their deuterated derivatives. Both molecules form hydrogen-bonded molecular crystals that are regarded to be model systems for polypeptides and proteins. The amide I bands of both ACN and NMA show a temperature-dependent sideband, while the NH bands are accompanied by a sequence of equidistantly spaced satellite peaks. These spectral anomalies are interpreted as a signature of vibrational self-trapping. Two different types of states can be identified in both crystals in the pump-probe signal: a delocalized free-exciton state and a set of localized self-trapped states. The phonons that mediate self-trapping in ACN and deuterated ACN are identified by their temperature dependence, confirming our previous results. The study shows that the substructure of the NH band in NMA (amide A and amide B bands) originates, at least partly, from vibrational self-trapping and not, as often assumed, from a Fermi resonance.

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“…The structure and vibrational spectra of N-methylacetamide (CH 3 -(CQO)-NH-CH 3 ) (NMA), a single amide containing methyl groups at both extremities, have been the subject of numerous investigations. [3][4][5][6][7][8] A complex study by incoherent inelastic and quasi-elastic neutron scattering, IR-spectroscopy, DSC, and neutron diffraction has revealed several unusual phenomena in this system, including dynamic transitions at about 230 K and 100 K, and has raised the question of a possible proton transfer. The authors of ref.…”

Section: Introductionmentioning

confidence: 99%

Dynamics of the intermolecular hydrogen bonds in the polymorphs of paracetamol in relation to crystal packing and conformational transitions: a variable-temperature polarized Raman spectroscopy study

Kolesov

Михайленко

Boldyreva

2011

Phys. Chem. Chem. Phys.

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The properties of the intermolecular hydrogen bonds in the monoclinic (Form I) and the orthorhombic (Form II) polymorphs of paracetamol, C(8)H(9)NO(2), have been studied by single crystal polarized Raman spectroscopy (40 to 3700 cm(-1)) in a wide temperature range (5 K < T < 300 K) in relation to the dynamics of methyl-groups of the two forms. A detailed analysis of the temperature dependence of the wavenumbers, bandwidths and integral intensities of the spectral bands has revealed an essential difference between the two polymorphs in the strength and ordering of OH···O and NH···O hydrogen bonds. The compression of intermolecular hydrogen bonds is interrelated with crystal packing and the dynamics of methyl-groups. On structural compression of the orthorhombic polymorph on cooling, a compromise is to be sought between the shortening of OH···O and NH···O bonds, attractive CH···O and repulsive CH···H contacts in the crystal structure. As a result of a steric conflict at temperatures below 100 K, N-H···O hydrogen bonds become significantly disordered, and an extended intramolecular transition from the conformation "staggered" with respect to the C=O bond to the one "staggered" with respect to the NH bond is observed. In most of the studied crystals this transition was only about 60% complete even at 5 K, but in some of the crystals the orientation of all the methyl-groups became staggered with respect to the NH bond at low temperatures. This complete transition was coupled to a sharp shortening of the OH···O and NH···O hydrogen bonds at <100 K, the appearance of new additional positions of the protons in these H-bonds, and a slight strengthening of the C-HO bonds formed by methyl-groups. The same conformational transition has been observed also in the monoclinic polymorph at T < 80 K. The crystal packing in Form I prevents the O-H···O hydrogen bonds from adopting the optimum geometry, and they are significantly disordered at all the temperatures, especially at ≤200 K. The packing of molecules in Form I is also not favourable to form C-H···O hydrogen bonds involving methyl-groups. One can conclude from the comparison of diffraction and spectroscopic data that the higher stability of Form I results not from a larger strength of individual OH···O and NH···O hydrogen bonds, but is a cumulative effect: all the hydrogen bonds together stabilize the structure of the monoclinic polymorph more than that of the orthorhombic polymorph.

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Dynamics of Crystalline N-Methylacetamide: Temperature Dependence of Infrared and Inelastic Neutron Scattering Spectra

Cited by 21 publications

References 17 publications

Polymorphism of Paracetamol: A New Understanding of Molecular Flexibility through Local Methyl Dynamics

Polymorphism of Paracetamol: A New Understanding of Molecular Flexibility through Local Methyl Dynamics

Spectral response of crystalline acetanilide andN-methylacetamide: Vibrational self-trapping in hydrogen-bonded crystals

Dynamics of the intermolecular hydrogen bonds in the polymorphs of paracetamol in relation to crystal packing and conformational transitions: a variable-temperature polarized Raman spectroscopy study

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