Dipolar shielding

Absence of any IR band in the region 3300-3600 cm suggests that the requisite conformation for intramolecular cyclopropane HO bonding can not be adopted the authors postulate that a compressional interaction may so distort the intramolecular electric helds as to bring about the dipolar shielding. 

Nuclear magnetic resonance (NMR) is a technique of considerable versatility in polymer science. It is used universally as a probe of chemical configurations, it provides information on the dynamics and relaxation times of a polymer system and it offers a route to the determination of orientation parameters, the exact route depending on the particular nuclei employed. In principle quadrupolar, dipolar, shielding tensor and indirect spin coupling interactions can all be employed " however, in practice only the first two have any universal appeal. Dipolar coupling using proton NMR offers the simplest approach in terms of material preparation and will be considered first. 

However, because of chemical shielding anisotropy (CSA) and quadnipolar and dipolar effects, the Lamior... 

A model for the mechanism of the highly enantioselective AlMe-BINOL-cata-lyzed 1,3-dipolar cycloaddition reaction was proposed as illustrated in Scheme 6.13. In the first step nitrone la coordinates to the catalyst 11b to form intermediate 12. In intermediate 13, which is proposed to account for the absolute stereoselectivity of this reaction, it is apparent that one of the faces of the nitrone, the si face, is shielded by the ligand whereas the re face remains available... 

Dipolar coupling and 3C shielding anisotropy cause unequal intensity of spinning side bands. The scalar coupling enabled magic angle rotation to distinguish two sets of sub-spectra.58... 

These routes are dimerization to furoxans 2 proceeding at ambient and lower temperatures for all nitrile oxides excluding those, in which the fulmido group is sterically shielded, isomerization to isocyanates 3, which proceeds at elevated temperature, is practically the only reaction of sterically stabilized nitrile oxides. Dimerizations to 1,2,4-oxadiazole 4-oxides 4 in the presence of trimethylamine (4) or BF3 (1 BF3 = 2 1) (24) and to 1,4,2,5-dioxadiazines 5 in excess BF3 (1, 24) or in the presence of pyridine (4) are of lesser importance. Strong reactivity of nitrile oxides is based mainly on their ability to add nucleophiles and particularly enter 1,3-dipolar cycloaddition reactions with various dipolarophiles (see Sections 1.3 and 1.4). 

For the heteronuclear dipole-dipole interaction, the spin I S whereas for the homonuclear dipolar or electric quadrupole interaction, I=S. For the anisotropic chemical shielding interaction, the spin operators are... 

When r s, one has interconversion between operators Br and Bs, and Rrs is a cross-relaxation rate. Note that the cross-relaxation may or may not contain interference effects depending on the indices l and /, which keep track of interactions Cyj and C,. Cross-correlation rates and cross-relaxation rates have not been fully utilized in LC. However, there is a recent report41 on this subject using both the 13C chemical shielding anisotropy and C-H dipolar coupling relaxation mechanisms to study a nematic, and this may be a fruitful arena in gaining dynamic information for LC. We summarize below some well known (auto-)relaxation rates for various spin interactions commonly encountered in LC studies. 

Composite-pulse decoupling schemes like WALTZ [36, 37], DIPSI [38], or GARP [39], which are used in solution-state NMR, have failed to offer any significant improvements in the solid state compared to CW decoupling. The residual line width in CW-decoupled spectra is dominated by a cross term between the chemical-shielding tensor of the protons and the heteronuclear dipolar-coupling tensor [40, 41]. 

Classical shielding arguments indicate an electron-rich phosphorus atom, or equally, an increase in coordination number. The silicon atom seems also to be electron-rich, while the carbon has a chemical shift in the range expected for a multiply bonded species. The coupling constant data are difficult to rationalize, as it is not possible to predict the influence of orbital, spin-dipolar, Fermi contact, or higher-order quantum mechanical contributions to the magnitude of the coupling constants. However, classical interpretation of the NMR data indicates that the (phosphino)(silyl)carbenes have a P-C multiple bond character. 

E) configuration. The dipolar cycloaddition of 141 with a silyl nitronate shows a slight increase of facial selectivity over 132 (Eq. 2.9). Because the cycloadducts are converted directly to the corresponding isoxazolines, only the facial selectivity can be determined. It is believed that the cycloaddition proceeds on the Re face of the dipolarophile due to shielding of the Si face by the auxihary. Both chiral auxiliaries can be liberated from the cycloadduct upon reduction with L-Selectride. 

The number of investigations on the enantioselective dipolar cycloaddition of nitronates is still rather limited. In the case of simple alkyl nitronates, the facial selectivity is controlled solely by the steric environment about the two faces of the chiral unit. For example, the reaction of steroid dipolarophile 270 proceeds with the nitronate approaching the Re face of the alkene (Eq. 2.23) (234). The facial selectivity is controlled by the C(19) methyl group, which blocks the Si face of the dipolarophile. Similarly, exposure of 279 to ethyl acrylate at 40 °C for 24 h, provides a single nitroso acetal (Scheme 2.21) (242). The facial selectivity is presumed to arise from steric shielding by the menthol group, however the full stereostructure has not been established. 

Akiyama et al. (180) overcame this problem by employing ch/ro-inositol derivatives as chiral auxiliaries for the acrylic ester, which afforded dipolar cycloadducts with a high degree of stereoselectivity (Scheme 6.34). Formation of the major products [(55)-isoxazoline-5-esters] was suggested to arise from the s-cis conformer of acrylate 27, the minor product being derived from the s-trans conformer 28. The bulky protective group (in this case tert-butyldiphenylsilyl) would effectively shield the Re face of the olefinic double bond and destabilize the s-trans conformer 28. 

Mukai et al. (36,37) applied the chiral tricarbonyl(r -arene)chromium(0)-derived nitrone 24b in 1,3-dipolar cycloadditions with various alkenes, such as styrene 25 (Scheme 12.11). The analogous nonmetallic nitrone 24a was used in a reference reaction with 25, giving the isoxazohdine 26a with an endo/exo ratio of 82 18. By the apphcation of nitrone 24b in the 1,3-dipolar cycloaddition with 25, the endo/exo-selectivity changed significantly to give exo-26b as the only observable product. The tricarbonylchromium moiety effectively shielded one face of the nitrone, leading to high diastereofacial selectivity. The product exo- 26b was obtained with 96-98% de. 

The optically pure tricarbonyl chromium(O) complexes 116 have proven to offer an effective shielding of one of the faces of the alkene. Complex 116 was subjected to a 1,3-dipolar cycloaddition with the sterically crowded nitrile oxide 117 (Scheme 12.39) (172). The reaction proceeds at room temperature to give a 70% yield of 118. After removal of the tricarbonylchromium moiety by a light induced oxidation with air, compound 119 was obtained with an optical purity of 98% enantiomeric excess (ee). 

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