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Shifts compounds

Bulo et al. <2004AG732> have studied the degenerate rearrangements that occur among bicyclic hydrocarbons with three-membered rings. Extending the work to include phosphorus resulted in the formation of compound 197. Compound 198 was heated to 50 °C and the Woodward-Hoffmann-allowed product for a [ l,5]-shift (compound 199) was produced (Scheme 17). [Pg.551]

Phosphorus nuclei have been used for many years in in vivo NMR, especially for intracellular pH measurements. However, because most organic phosphates have similar chemical shifts, compound identification can be difficult without special attention being paid to culture conditions in the NMR tube.15 Carbon NMR also yields significant results because of the large chemical shift dispersion and narrow lines of this nucleus. 13C spectra reflect most of the chemical rearrangements that may take place between substrate and final product. [Pg.191]

Compounds Chemical Shifts Compounds Chemical Shifts ... [Pg.12]

Se chemical shifts Compound Solvent ppm Reference... [Pg.468]

In addition to the normal photochemical reactions of saturated ketones, p,y-unsaturated carbonyl compounds undergo carbonyl migration via a [1,3] shift. Compound 139 in Scheme 45 represents a typical example. Compounds with an alkyl substituent in the P position such as 140 may also undergo a Norrish type II reaction (Kiefer and Carlson, I%7), while for ketones with electron-rich double bonds such as 141, oxetane formation is also observed (Schexnayder and Engel, 1975). [Pg.460]

Nevertheless, it is possible to convert a racemic sample with chiral reagents into diastereomers or simply to dissolve it in an enantiomericaUy pure solvent R or S following this process, solvation diasteromers arise from the racemate (RP + SP) of the sample P, e.g. R RP and R SP, in which the enantiomers are recognisable because of their different shifts. Compounds with groups which influence the chemical shift because of their anisotropy effect (see Sections 2.5.1 and 2.5.2) are suitable for use as chiral solvents, e.g. 1-phenylethylamine and 2,2,2-trifluoro-l-phenylelhanol. ... [Pg.34]

NMR and ESR spectroscopy applied to gold and silver compounds TABLE 2. Representative silver 109 chemical shifts Compound or ion... [Pg.75]

For fluorescent compounds and for times in die range of a tenth of a nanosecond to a hundred microseconds, two very successftd teclmiques have been used. One is die phase-shift teclmique. In this method the fluorescence is excited by light whose intensity is modulated sinusoidally at a frequency / chosen so its period is not too different from die expected lifetime. The fluorescent light is then also modulated at the same frequency but with a time delay. If the fluorescence decays exponentially, its phase is shifted by an angle A([) which is related to the mean life, i, of the excited state. The relationship is... [Pg.1123]

A relatively small training set of 744 NMR chemical shifts for protons from 1 20 molecular structures was collected from the literature. This set was designed to cover as many situations of protons in organic structures as possible. Only data from spectra obtained in CDCl, were considered. The collection was restricted to CH protons and to compounds containing the elements C, H, N, 0, S, F, Cl, Br. or I. [Pg.524]

Fast and accurate predictions of H NMR chemical shifts of organic compounds arc of great intcrc.st for automatic stnicturc elucidation, for the analysi.s of combinatorial libraries, and, of course, for assisting experimental chemists in the structural characterization of small data sets of compounds. [Pg.524]

In a reaction, bonds are broken and made. In some cases free electrons are shifted also. The rcaciion center contains all the bond.s being broken or made during the reaction as well as all the electron rearrangement processes. The reaction uhstme-ture is the structural subunit of atoms and bonds around the reaction center that has to be present in a compound in order for the reaction to proceed in the foi"ward (synthesis) direction (Figure 10,3-32). Both characteristics of a reaction can be used to. search for reactions with an identical reaction center and reaction substructure but with different structural units beyond the reaction substructure. For example, this can be achieved by searching in a reaction database. [Pg.571]

On the basis of the studies described in the preceding chapters, we anticipated that chelation is a requirement for efficient Lewis-acid catalysis. This notion was confirmed by an investigation of the coordination behaviour of dienophiles 4.11 and 4.12 (Scheme 4.4). In contrast to 4.10, these compounds failed to reveal a significant shift in the UV absorption band maxima in the presence of concentrations up to one molar of copper(ir)nitrate in water. Also the rate of the reaction of these dienophiles with cyclopentadiene was not significantly increased upon addition of copper(II)nitrate or y tterbium(III)triflate. [Pg.110]

After in situ neutralisation, the complexation behaviour of 4.44 was studied using UV-vis spectroscopy. The absorption maximum of this compound shifted from 294 nm in pure water to 310 nm in a 10 mM solution of copper(II)nitrate in water. Apparently, 4.44, in contrast to 4.42, does coordinate to copper(II)nitrate in water. [Pg.115]

The desired pyridylamine was obtained in 69 % overall yield by monomethylation of 2-(aminomethyl)pyridine following a literature procedure (Scheme 4.14). First amine 4.48 was converted into formamide 4.49, through reaction with the in situ prepared mixed anhydride of acetic acid and formic acid. Reduction of 4.49 with borane dimethyl sulfide complex produced diamine 4.50. This compound could be used successfully in the Mannich reaction with 4.39, affording crude 4.51 in 92 % yield (Scheme 4.15). Analogous to 4.44, 4.51 also coordinates to copper(II) in water, as indicated by a shift of the UV-absorption maximum from 296 nm to 308 nm. [Pg.116]

Studies on a large number of aromatic compounds have revealed that for CTAB the largest shift occurs for the alkyl chain protons near the surfactant headgroup, whereas in SDS nearly all proton signals are shifted significantly " ". For SDS, the most pronounced shifts are observed for protons around the centre of the chain. This result has been interpreted in terms of deeper penetration of... [Pg.145]

The aromatic shifts that are induced by 5.1c, 5.If and S.lg on the H-NMR spectrum of SDS, CTAB and Zn(DS)2 have been determined. Zn(DS)2 is used as a model system for Cu(DS)2, which is paramagnetic. The cjkcs and counterion binding for Cu(DS)2 and Zn(DS)2 are similar and it has been demonstrated in Chapter 2 that Zn(II) ions are also capable of coordinating to 5.1, albeit somewhat less efficiently than copper ions. Figure 5.7 shows the results of the shift measurements. For comparison purposes also the data for chalcone (5.4) have been added. This compound has almost no tendency to coordinate to transition-metal ions in aqueous solutions. From Figure 5.7 a number of conclusions can be drawn. (1) The shifts induced by 5.1c on the NMR signals of SDS and CTAB... [Pg.145]


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13C NMR Chemical Shifts and Coupling Constants of Organometallic Compounds

Aromatic compounds carbon-13 chemical shifts

Aromatic compounds proton chemical shifts

Aromatic compounds, chemical shifts

Carbon 13 chemical shifts ethyl compounds

Carbon 13 chemical shifts paramagnetic compounds

Carbonyl compounds shifts

Chemical shift in organic compounds

Chemical shift polycyclic aromatic compounds

Chemical shift reference compounds

Chemical shifts biochemical compounds

Chemical shifts of tin compounds

Chemical shifts organogermanium compounds

Compound semiconductors Knight shifts

Coordination compounds shifts

Europium compounds, chiral shift reagents

F Chemical Shifts of Sulfur Compounds

Gold compounds, isomer shift

Heterocyclic boron compounds shifts

Hydride shifts reactions with carbonyl compounds

Hydroxylation of Unsaturated or Aromatic Compounds and the NIH Shift

Iodine compounds, isomer shift

Iron-57 compounds chemical isomer shift

Isomer shift compounds

Lanthanide shift reagents carbonyl compound complexes

NIH shift aromatic compounds

Neptunium compounds isomer shift

Organic compounds characteristic 13C chemical shifts

Organic compounds characteristic proton chemical shifts

Organolead compounds shifts 299

Organometallic compounds shifts

Organosilicon compounds shifts

Organosilicone compounds 29Si chemical shifts

Organosulfur compounds shifts 234

Proton chemical shifts of compound

Proton chemical shifts of reference compounds

Shifts in Specific Classes of Compound

Stannous compounds, isomer shift

Ylide compounds 1.4- hydrogen shift

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