Raman spectroscopy hydrogen bonds

Intimate information about the nature of the H bond has come from vibrational spectro.scopy (infrared and Raman), proton nmr spectroscopy, and diffraction techniques (X-ray and neutron). In vibrational spectroscopy the presence of a hydrogen bond A-H B is manifest by the following effects ... 

In reality, several factors were mentioned as being responsible for this behavior, such as variations in bond angle distortion, in the internal stress or in the hydrogen content [40, 76], but all of them are also strongly correlated with the variation of optical gap width in amorphous carbon films. Theoretical work on Raman spectroscopy on DLC materials gave additional support for Dillon s interpretation [77]. 

There are two major experimental techniques that can be used to analyze hydrogen bonding in noncrystalline polymer systems. The first is based on thermodynamic measurements which can be related to molecular properties by using statistical mechanics. The second, and much more powerful, way to elucidate the presence and nature of hydrogen bonds in amorphous polymers is by using spectroscopy (Coleman et al., 1991). From the present repertoire of spectroscopic techniques which includes IR, Raman, electronic absorption, fluorescence, and magnetic resonance spectroscopy, the IR is by far the most sensitive to the presence of hydrogen bonds (Coleman et al., 1991). 

It was proposed (Johnson et al., 1987a) that this local lattice dilation is stabilized by the direct incorporation of hydrogen atoms through the coordinated formation of Si—H bonds. Results from SIMS (Section III. 1) and Raman spectroscopy (following) are consistent with this view. For example, the 60-min deuterium profile in Fig. 7(b) yields an integrated areal density of D in the near-surface peak of —1.7 x 1014 cm-2. The same deuteration conditions applied to this material produced 5 x 10n platelets per cm2 with an average diameter of 7 nm (Ponce et al., 1987). 

Me2SnF4]2-[NH4]+2 Mossbauer and IR, Raman spectroscopy. The methyl groups are trans to each other. Normal N—H- F hydrogen bonds. 153... 

Upon dilution in solvents which may associate via hydrogen bonds (water, methanol, dioxane) the situation is more complex. I.R. and Raman spectroscopy indicate the formation of various monomer-solvent complexes (4, 6). The corresponding absorption bands are in the same range as the characteristic bands for open dimers and oligomers and the latter cannot therefore be determined quantitatively. However, the viscosity of carboxylic acids was found to rise upon addition of water or methanol (4, 7) suggesting that these solvents bind together "oligomers". The persis-... 

For organic hydrogen bonds, methanol takes the role that HF has for inorganic hydrogen bonds it is the simplest conceivable prototype. Its cluster spectroscopy has been reviewed together with that of water clusters [98], While the monomer vibrational dynamics is in general well-studied [214 217], different values for the fundamental O—H stretching band center are in use [63, 64, 75, 173, 189, 218]. Based on combined Raman and IR evidence, a value of 3684 3686 cm 1 appears well-justified [16, 65, 77, 82, 216]. It serves as an important reference for vibrational red shifts in methanol clusters. 

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