The accurate analysis of infrared spectra (both wavenumbers and intensities) of (E)-4-(dimethylamino)-1,1,1-trifluorobut-3-en-2-one (DMTBN) and (E)-4-(hexadeutero-dimethylamino)-1,1,1-trifluorobut-3-en-2-one (d6-DMTBN) revealed that besides intramolecular hydrogen bond in the (EE) conformer, these enaminoketones form cyclic dimers between the (EZ) and (EE) conformers due to intermolecular hydrogen bonds, namely, O=C and . Evaluation of constant and enthalpy of formation of these H-bonds revealed that O=C bond has greater and more negative than bond (cf. 214.4?M?1, ?21.7?kJ?M?1dm3, and 16.4?M?1, ?6.7?kJ?M?1dm3, resp.). Consequently, stronger H-bond ?O=C is formed in the first place, whereas weaker H-bond is formed afterward. Moreover, formation of intermolecular hydrogen bond has influence on C–F vibrations, but analysis of this influence must take into account the fact that these vibrations in some cases are coupled with . True enthalpy of the equilibrium (EZ)?(EE) is positive (25.3?kJ?M?1dm3), thus confirming results of DFT calculations, according to which the (EZ) conformer is more stable than the (EE) one. 1. Introduction From spectroscopic experiments Allerhand and Schleyer [1] qualitatively concluded that the ability of a C–H group to form weak hydrogen bonds depends on carbon hybridization, as C(sp1)–H > C(sp2)–H > C(sp3)–H and increases with the number of adjacent electron-withdrawing groups. The enhancement of the C–H donor strength by neighboring electronegative groups is often called “activation” of C–H. It is well known that hydrogen bonds in general are composed of different types of interactions [2]. As for all intermolecular interactions, there is a nondirectional “van-der-Waals” contribution, which is weakly bonding at long distances (by dispersion forces) and strongly nonbonding at short distances (by exchange repulsion). At their optimal geometry, van der Waals interactions contribute about 1?kJ?mol?1 to the hydrogen bond energy. An electrostatic component (dipole-dipole, dipole-charge, etc.) is directional and bonding at all distances. It reduces with increasing distance and with reducing dipole moments or charge involved. For donors like O–H or N–H, the electrostatic component is the dominant one in hydrogen bond (several kJ mol?1). This is also true for strongly polarized C–H groups (up to 8?kJ?mol?1), whereas for weakly polarized C–H groups the electrostatic component is of similar magnitude to the van der Waals contribution [3]. Only for the strongest types of hydrogen bonds does a charge-transfer component become important [2]; it
References
[1]
A. Allerhand and P. V. R. Schleyer, “A survey of C–H groups as proton donors in hydrogen bonding,” Journal of the American Chemical Society, vol. 85, no. 12, pp. 1715–1723, 1963.
[2]
G. A. Jeffrey and W. Saenger, Hydrogen Bonding in Biological Structures, Springer, Berlin, Germany, 1991.
[3]
T. Steiner, “Unrolling the hydrogen bond properties of interactions,” Chemical Communications, pp. 727–734, 1997.
[4]
M. Gussoni and C. Castiglioni, “Infrared intensities. Use of the CH-stretching band intensity as a tool for evaluating the acidity of hydrogen atoms in hydrocarbons,” Journal of Molecular Structure, vol. 521, no. 1–3, pp. 1–18, 2000.
[5]
J. P. Bégué and D. Bonnet-Delton, “Biological impacts of fluorination: pharmaceuticals based on natural products,” in Fluorine and Health. Molecular Imaging, Biomedical Materials and Pharmaceuticals, A. Tressaud and G. Haufe, Eds., p. 554, Elsevier, Amsterdam, The Netherlands, 2008.
[6]
J. T. Kiss, K. Felf?ldi, and I. Pálinko, “Changes in the aggregation patterns of Z-2,3-diphenylpropenoic acid and its methyl ester on substituting the olefinic hydrogen with CF3 group-an FT-IR study,” Journal of Molecular Structure, vol. 744–747, pp. 207–210, 2005.
[7]
B. Tolnai, J. T. Kiss, K. Felf?ldi, and I. Pálinko, “C– H?F hydrogen bonds as the organising force in F-substituted α-phenyl cinnamic acid aggregates studied by the combination of FTIR spectroscopy and computations,” Journal of Molecular Structure, vol. 924–926, p. 27, 2009.
[8]
S. I. Vdovenko, I. I. Gerus, and V. P. Kukhar, “Conformational analysis of push-pull enaminoketones using Fourier transform IR, NMR spectroscopy, and quantum chemical calculations. I. β-Dimethylaminovinyl methyl ketone, β-dimethylaminovinyl trifluoromethyl ketone and their deuterated derivatives,” Vibrational Spectroscopy, vol. 52, pp. 144–153, 2010.
[9]
S. I. Vdovenko, I. I. Gerus, V. Olga Balabon, and V. P. Kukhar, “The conformational analysis of push- pull enaminoketones using Fourier transform IR and NMR spectroscopy, and quantum chemical calculations. III. alfa-Dialkylaminovinyl perfluoromethyl ketones and alfa-dialkylaminovinyl trichloromethyl ketones,” Trends in Organic Chemistry. In press.
[10]
H. Raissi, A. Nowroozi, M. Roozbeh, and F. Farzad, “Molecular structure and vibrational assignment of (trifluoroacetyl) acetone: a density functional study,” Journal of Molecular Structure, vol. 787, no. 1–3, pp. 148–162, 2006.
[11]
M. Zahedi-Tabrizi, F. Tayyari, Z. Moosavi-Tekyeh, A. Jalali, and S. F. Tayyari, “Structure and vibrational assignment of the enol form of 1,1,1-trifluoro-2,4-pentanedione,” Spectrochimica Acta A, vol. 65, no. 2, pp. 387–396, 2006.
[12]
A. V. Iogansen, “Direct proportionality of the hydrogen bonding energy and the intensification of the stretching ν (XH) vibration in infrared spectra,” Spectrochimica Acta A, vol. 55, no. 7-8, pp. 1585–1612, 1999.
[13]
P. J. A. Ribeiro-Carlo and P. D. Vaz, “Towards the understanding of the spectroscopic behaviour of the C–H oscillator in hydrogen bonds: the effect of solvent polarity,” Chemical Physics Letters, vol. 390, pp. 358–361, 2004.
[14]
G. Lui, L. Ping, and H. Li. Spectrochim, “ hydrogen bond in chloroform-triformylmethane complex: blue-shifted or red-shifted?” Acta Part A, vol. 66, pp. 643–645, 2007.
[15]
P. J. Taylor, “The i.r. spectroscopy of some highly conjugated systems-I. Rationale of the investigation,” Spectrochimica Acta A, vol. 32, no. 8, pp. 1471–1476, 1976.
[16]
R. A. Nyquist, Interpreting Infrared, Raman, Nuclear Magnetic Resonance Spectra, vol. 1, Academic Press, 2001.
[17]
D. Smith and P. J. Taylor, “The i.r. spectroscopy of some highly conjugated systems-II. Conformational effects in simple enamino-ketones. A note on 4-pyridone,” Spectrochimica Acta A, vol. 32, no. 8, pp. 1477–1488, 1976.
[18]
A. R. Nekoe, S. F. Tayyari, M. Vakii, S. Holakoei, A. H. Hamodian, and R. E. Sammelson, “Conformation and vibrational spectra and assignment of 2-thenoyltrifluoroacetone,” Journal of Molecular Structure, vol. 932, pp. 112–122, 2009.
[19]
M. Gussoni, “Role of vibrational intensities in the determination of molecular structure and charge distribution,” Journal of Molecular Structure, vol. 113, pp. 323–340, 1984.
[20]
M. Gussoni, C. Casiglioni, and G. Zerbi, “Physical meaning of electrooptical parameters derived from infrared intensities,” Journal of Physical Chemistry, vol. 88, p. 341, 1984.
[21]
M. Gussoni, “Infrared intensities: a new tool in chemistry,” Journal of Molecular Structure, vol. 141, pp. 63–92, 1986.
[22]
C. Casiglioni, M. Gussoni, and G. Zerbi, “Characteristic infrared intensities of CH bonds,” Journal of Molecular Structure, vol. 141, pp. 341–346, 1986.
[23]
A. V. Iogansen, “IK-spektroskopiya i opredeleniye energii vodorodnoy svyazi (IR-spectroscopy and evaluation of hydrogen bond energy),” in Vodorodnaya Svyaz (the Hydrogen Bond), N. D. Sokolov, Ed., pp. 112–155, Izd. Nauka, Moscow, Russia, 1981.
