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NMR synthesis

Aryl- Grignard addition to the imines gave a 1 1 mixture of diastereomers which could be separated by chiral HPLC but in most cases are identified by NMR. Synthesis of the achiral raeso-diastereoisomer via an Asulfamoyloxazolidinone intermediate confirmed the identity of the three peaks seen in the chiral HPLC chromatograph [22]. [Pg.303]

Fig. 3 Ti-relaxation time and concentration of different nuclei in the course of the zeolite-A synthesis. H- H-NMR 23Na-23Na-NMR 37a1-27ai nmr (synthesis conditions as in Fig. 1). The method is based on fast conversion from T measurements to measurements of intensity of NMR signal M. At the zero time signal is dynamically cancelled so, above, abscissa intensities, and below, changes in relaxation T are obtained... Fig. 3 Ti-relaxation time and concentration of different nuclei in the course of the zeolite-A synthesis. H- H-NMR 23Na-23Na-NMR 37a1-27ai nmr (synthesis conditions as in Fig. 1). The method is based on fast conversion from T measurements to measurements of intensity of NMR signal M. At the zero time signal is dynamically cancelled so, above, abscissa intensities, and below, changes in relaxation T are obtained...
It must be emphasized that NMR is first and foremost a tool for structural analysis and, in addition to the petroleum analyses described above, the technique (phosphorus NMR and sometimes nitrogen NMR) is abundantly used in all petrochemical synthesis operations. [Pg.69]

For many years the synthesis and chemical properties of allenes has been a major area of interest in this laboratory. In our NMR research group we studied the H and lie behaviour of these compounds. [Pg.253]

The amino add analysis of all peptide chains on the resins indicated a ratio of Pro Val 6.6 6.0 (calcd. 6 6). The peptides were then cleaved from the resin with 30% HBr in acetic acid and chromatogra phed on sephadex LH-20 in 0.001 M HCl. 335 mg dodecapeptide was isolated. Hydrolysis followed by quantitative amino acid analysis gave a ratio of Pro Val - 6.0 5.6 (calcd. 6 6). Cycll2ation in DMF with Woodward s reagent K (see scheme below) yielded after purification 138 mg of needles of the desired cyc-lododecapeptide with one equiv of acetic add. The compound yielded a yellow adduct with potassium picrate, and here an analytically more acceptable ratio Pro Val of 1.03 1.00 (calcd. 1 1) was found. The mass spectrum contained a molecular ion peak. No other spectral measurements (lack of ORD, NMR) have been reported. For a thirty-six step synthesis in which each step may cause side-reaaions the characterization of the final product should, of course, be more elaborate. [Pg.236]

Simple and Complex Organic Molecules. Using modem direct fluorination technology, the synthesis of even the most complex perfluorocarbon stmctures from hydrocarbon precursors is now possible. For example, syntheses of the first perfluoro crown ethers, perfluoro 18-crown-6, perfluoro 15-crown-5, and perfluoro 12-crown-4 (54) have been reported. Perfluoro crown ethers (54,55) are becoming important as the molecules of choice for many F-nmr imaging appHcations (56) in humans and are particularly effective in brain and spinal diagnostics when... [Pg.278]

Pubhcations have described the use of HFPO to prepare acyl fluorides (53), fluoroketones (54), fluorinated heterocycles (55), as well as serving as a source of difluorocarbene for the synthesis of numerous cycHc and acycHc compounds (56). The isomerization of HFPO to hexafluoroacetone by hydrogen fluoride has been used as part of a one-pot synthesis of bisphenol AF (57). HFPO has been used as the starting material for the preparation of optically active perfluorinated acids (58). The nmr spectmm of HFPO is given in Reference 59. The molecular stmcture of HFPO has been deterrnined by gas-phase electron diffraction (13). [Pg.304]

Poly(ethylene oxide). The synthesis and subsequent hydrolysis and condensation of alkoxysilane-terniinated macromonomers have been studied (39,40). Using Si-nmr and size-exclusion chromatography (sec) the evolution of the siUcate stmctures on the alkoxysilane-terniinated poly(ethylene oxide) (PEO) macromonomers of controlled functionahty was observed. Also, the effect of vitrification upon the network cross-link density of the developing inorganic—organic hybrid using percolation and mean-field theory was considered. [Pg.329]

The synthesis of natural products containing the quinonoid stmcture has led to intensive and extensive study of the classic diene synthesis (77). The Diels-Alder cycloaddition of quinonoid dienophiles has been reported for a wide range of dienes (78—80). Reaction of (2) with cyclopentadiene yields (79) [1200-89-1] and (80) [5439-22-5]. The analogous 1,3-cyclohexadiene adducts have been the subject of C-nmr and x-ray studies, which indicate the endo—anti—endo stereostmcture (81). [Pg.413]

Acetates. Because of the significant interest in selective acetylation reactions of sucrose, the need for a convenient and unambiguous method of identification has been recognized (34,35). The position of an acetyl group in a partially acetylated sucrose derivative can be ascertained by comparison of its H-nmr acetyl methyl proton resonances after per-deuterioacetylation with those of the assigned octaacetate spectmm. The synthesis of partially acetylated sucroses has generally been achieved either by way of selectively protected derivatives such as trityl ethers and cychc acetals or by direct selective acetylation and deacetylation reactions. [Pg.33]

The poly(vinyl alcohol) made for commercial acetalization processes is atactic and a mixture of cis- and /n j -l,3-dioxane stereoisomers is formed during acetalization. The precise cis/trans ratio depends strongly on process kinetics (16,17) and small quantities of other system components (23). During formylation of poly(vinyl alcohol), for example, i j -acetalization is more rapid than /ra/ j -acetalization (24). In addition, the rate of hydrolysis of the trans-2iQ. -A is faster than for the <7 -acetal (25). Because hydrolysis competes with acetalization during acetal synthesis, a high cis/trans ratio is favored. The stereochemistry of PVF and PVB resins has been studied by proton and carbon nmr spectroscopy (26—29). [Pg.450]

In the structure sections, labelled compounds have often been used to solve a spectroscopic problem involved in microwave (Section 4.04.1.3.2), nitrogen NMR (Section 4.04.1.3.5), IR (Section 4.04.1.3.7(i)) or mass spectrometry (Section 4.04.1.3.8). The synthesis usually involves non-radioactive compounds ( H, N) by classical methods that must be repeated several times in order to obtain good yields. [Pg.289]

The review by Takeuchi and Ferusaki is quite encompassing and, in addition to synthesis and reactivity, the physical and spectroscopic properties of isoxazolidines are discussed in detail. Additional spectral studies on the parent and derivatives include H NMR (68MI41600, 77H(7)201, 78IZV850). [Pg.6]

Acetic acid, dehydro- — see also Pyran-2-one, 3-acetyl-4-hydroxy-6-methyl-fungicidal properties, 3, 883 H NMR, 3, 581 reactions, 3, 690 with amines, 3, 700 reduction, 3, 843 synthesis, 2, 90 tautomerism, 3, 643... [Pg.508]

Adenine, 9-y3-D-arabinofuranosyl-occurrence, 5, 602 as pharmaceutical, 1, 160 Adenine, N -benzoyl-glycosylation, 5, 536 Adenine, 1-benzyl-benzylation, 5, 530 Adenine, 3-benzyl-benzylation, 5, 530 N NMR, 5, 515 synthesis, 5, 594 Adenine, 6-benzyl- N NMR, 5, 515 Adenine, 7-benzyl-benzylation, 5, 530 Adenine, N -benzyl-methylation, 5, 530 occurrence, 5, 602... [Pg.512]

H-Azepine, 2-(o-hydroxyphenyl)-synthesis, 7, 538 3 H-Azepine, methyl- H NMR, 7, 495 3H-Azepine, 3-methylring inversion barrier, 7, 14 3 H-Azepine, 2-methylene-isomerization, 7, 505 3H-Azepine, 7-(N-phthalimido) synthesis, 7, 538 4H-Azepine, 4,5-dihydro-cyclization, 7, 524... [Pg.523]

Schmidt reaction of ketones, 7, 530 from thienylnitrenes, 4, 820 tautomers, 7, 492 thermal reactions, 7, 503 transition metal complexes reactivity, 7, 28 tungsten complexes, 7, 523 UV spectra, 7, 501 X-ray analysis, 7, 494 1 H-Azepines conformation, 7, 492 cycloaddition reactions, 7, 520, 522 dimerization, 7, 508 H NMR, 7, 495 isomerization, 7, 519 metal complexes, 7, 512 photoaddition reactions with oxygen, 7, 523 protonation, 7, 509 ring contractions, 7, 506 sigmatropic rearrangements, 7, 506 stability, 7, 492 N-substituted mass spectra, 7, 501 rearrangements, 7, 504 synthesis, 7, 536-537... [Pg.524]

Azetidine, 7V-bromo-, 7, 240 Azetidine, AT-r-butyl- N NMR, 7, 11 Azetidine, AT-t-butyl-3-chloro-transannular nucleophilic attack, 7, 25 Azetidine, 3-chloro-isomerization, 7, 42 Azetidine, AT-chloro-, 7, 240 dehydrohalogenation, 7, 275 Azetidine, 7V-chloro-2-methyl-inversion, 7, 7 Azetidine, 3-halo-synthesis, 7, 246 Azetidine, AT-halo-synthesis, 7, 246 Azetidine, AT-hydroxy-synthesis, 7, 271 Azetidine, 2-imino-stability, 7, 256 Azetidine, 2-methoxy-synthesis, 7, 246 Azetidine, 2-methyl-circular dichroism, 7, 239 optical rotatory dispersion, 7, 239 Azetidine, AT-nitroso-deoxygenation, 7, 241 oxidation, 7, 240 synthesis, 7, 246 Azetidine, thioacyl-ring expansion, 7, 241 Azetidine-4-carboxylic acid, 2-oxo-oxidative decarboxylation, 7, 251 Azetidine-2-carboxylic acids absolute configuration, 7, 239 azetidin-2-ones from, 7, 263 synthesis, 7, 246... [Pg.525]

See other pages where NMR synthesis is mentioned: [Pg.124]    [Pg.45]    [Pg.124]    [Pg.245]    [Pg.320]    [Pg.1032]    [Pg.164]    [Pg.164]    [Pg.124]    [Pg.45]    [Pg.124]    [Pg.245]    [Pg.320]    [Pg.1032]    [Pg.164]    [Pg.164]    [Pg.67]    [Pg.229]    [Pg.536]    [Pg.164]    [Pg.149]    [Pg.157]    [Pg.230]    [Pg.174]    [Pg.287]    [Pg.508]    [Pg.509]    [Pg.512]    [Pg.516]    [Pg.517]    [Pg.517]    [Pg.518]    [Pg.518]    [Pg.519]    [Pg.520]    [Pg.520]    [Pg.521]    [Pg.525]   
See also in sourсe #XX -- [ Pg.273 ]

See also in sourсe #XX -- [ Pg.27 , Pg.36 ]



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