Chemical shift characteristic values

The contributions of the first three types are practically local in character they are close in value for two protons with similar structural environment, such as the ethylenic- and aromatic-type protons. It is only the last term in Eq. (35) that defines the values of the chemical shifts characteristic of aromatic or antiaromatic compounds. 

The extensive delocalization and aromatic character of pyridones, pyrones, etc. are shown by their chemical shift and coupling constant values (Table 8). By contrast, pyrans and thiins show chemical shifts characteristic of alkenic systems (Table 9). For these and for rings containing only a single endocyclic bond (Table 10), H NMR spectroscopy offers a most useful tool for structure determination. 

It is possible to explain the described regularities in changes of the spectral characteristics of water on rehydration of cells as follows. If the amounts of water in cells do not exceed a certain critical value, then water in dehydrated cells is localized mainly in cellular membranes (around protein molecules and other charged functionalities) and hydration shells of organelles and biomacromolecules. Such water (a portion of protons from this water) has a low value of the chemical shift characteristic for water molecules not participating in the hydrogen bonds as proton donors. 

The C chemical shift ranges for organic compounds in Table 2.2 show that many carbon-containing functional groups can be identified by the characteristic shift values in the C NMR spectra. 

The Se NMR chemical shifts of Se-N compounds cover a range of >1500 ppm and the value of the shift is characteristic of the local environment of the selenium atom. As a result, Se NMR spectra can be used to analyse the composition of a complex mixture of Se-N compounds. For example, Se NMR provides a convenient probe for analyzing the decomposition of selenium(IV) diimides RN=Se=NR e.g., R = Bu). By this method it was shown that the major decomposition products are the six-membered ring (SeN Bujs, the five-membered ring Sc3(N Bu)2 and fifteen-membered ring Sc9(N Bu)6 (Figure 3.2 and Section 6.3). 

In the benzene series, an approximately linear relationship has been obtained between the chemical shifts of the para-hydrogen in substituted benzenes and Hammett s a-values of the substituents. Attempts have been made, especially by Taft, ° to use the chemical shifts as a quantitative characteristic of the substituent. It is more difficult to correlate the chemical shifts of thiophenes with chemical reactivity data since few quantitative chemical data are available (cf. Section VI,A). Comparing the chemical shifts of the 5-hydrogen in 2-substituted thiophenes and the parahydrogens in substituted benzenes, it is evident that although —I—M-substituents cause similar shifts, large differences are obtained for -j-M-substituents indicating that such substituents may have different effects on the reactivity of the two aromatic systems in question. Differences also... 

Carbon-13 chemical shifts of the a- and (8-carbon atoms of various unsubstituted and 3-substituted thietane oxides and dioxides have been recorded and correlated by the equations S = ay + bx and Sf = ax + by where a and b are parameters characteristic of the sulfoxide or sulfone (y) and the substituent (x)216. The values of the substituent parameters were found to parallel those which determine the effect on the 13C chemical shifts when hydrogen is replaced by a substituent224. 

The standard is typically tetramethylsilane, Si(CH )4, which has a lot of protons and dissolves in many samples without reaction. Each group has a characteristic chemical shift, although the precise value depends on the other groups attached to the group of interest. For instance, if we observe a resonance at 8 = 1, we can be reasonably confident that it arises from a methyl group in an alcohol. 5 ... 

The 13C NMR spectral data for 9, 16, and 17 are shown in Table 2. The chemical shifts of carbonyl carbons of anthraquinones are characteristically observed at about 180 ppm.9 The chemical shifts for carbonyl carbons of 1,4-naphthoquinone and 1,4-benzoquinone appear at about 185 ppm, while those of carbonyl carbons adjacent to a methylene or methyl carbon are at about 200 ppm. The chemical shifts of the Cl and C4 of 9 are observed at 200.8 ppm and assigned to the 1,4-diketo form 9a. In the 13C spectrum of 17, the chemical shifts of carbonyl carbons are at 199.9 and 172.2 ppm. The former value corresponds to a carbonyl carbon adjacent to the methylene carbon, and the latter corresponds to the carbonyl carbon in the 9-position. The methylene carbons of 17 show two signals at 34.5 and 23.8ppm. From these results, 17 is considered to exist exclusively as an unsymmetrical 4,9-diketo form, 17a. Thus, these NMR spectral data suggest... 

Both the 13C chemical shifts and the F—C coupling constants for CF2 carbons are quite characteristic in value, as can be seen from the examples in Scheme 4.9. A review article on 13C NMR spectra of fluorinated cyclopropanes has recently appeared.3... 

In any case, it is worthwhile to point out that the observation of such unusually prolonged 13C T, values or displacement of the 13C chemical shifts can be utilized as a characteristic means to be able to locate a possible site for the presence of restricted or ceased group rotations for either methyl or hydroxymethyl groups caused by short interatomic contact or strong interactions. 

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