Methylene hydrogens

Removal of a methylene hydrogen of the acetylacetonc to form acetyl-acetone anion ... 

Replacing one of them by some different atom or group gives the enantiomer of the structure obtained by replacing the other therefore the methylene hydrogens at C 2 of butane are enantiotopic The same is true for the hydrogens at C 3... 

The NMR spectrum of the syn isomer shows evidence of a diamagnetic ring current, based on both the relatively low-field position of the vinylic hydrogens and the upfield shift of the methylene hydrogens. The anti isomer shows much less pronounced shifts. The X-ray crystal structure of the syn isomer shows a moderate level of bond alternation, ranging ftom 1.36 to 1.45 A (Fig. 9.4A). In the anti isomer, bond alternation is more pronounced, vith the double bond in the center ring being essentially a localized double bond (Fig. 9.4B). 

Replacement of a vinylidene fluonde unit by an e ylene or propylene unit in a locally perfluonnated cham environment greatly reduces the acidity ot the methylene hydrogens Copolymers of TFE and propylene are therefore considerably more resistant to bases and polar solvents than VDF-based elastomers TFE and propylene form a highly altematmg structure... 

Cyanacctie ester has similar propeities to malonic ester, inasmuch as the methylene hydrogen is icpiaceabic by sodium and thus hy alkyl gioups. 

PVAc is known to contain a significant number of long chain branches. Branches to the acetate methyl may arise by copolymerization of the VAe macromonomcr produced as a consequence of transfer to monomer (Section 6.2.6.2). Transfer to polymer may involve either the acetate methyl hydrogens (Scheme 6.34) or the methine (Scheme 6.35) or methylene hydrogens of the polymer backbone. 

The same equatorial preference is also manifested in the 3,3-disubstituted thietane oxides66,194. Thus, the NMR spectra of 5e,f contain two Me singlets at 1.23 and 1.30 ppm and two methylene multiplets at 3.03 and 3.53 ppm (in CDC13). The large difference in the chemical shifts of the axial and equatorial a-methylene hydrogens is characteristic of an axial nonbonded electron pair on sulfur (conformation 5e equation 73). This conformational preference is corroborated by the small differences in the chemical shifts of the two methyl groups, and fits the contention that 1,3-diaxial interactions are responsible for this ultimate result. Certainly, these interactions are greater in the conformer 5f. 

Beside thioamides, dithioesters are the most stable and accessible thiocarbonyl compounds. Their specific reactivity, in particular towards nucleophiUc reagents and their apphcations to the formation of carbon-carbon bonds, have already been reviewed [8]. However, as shown below, the presence of a phosphonate function alpha or beta to the thiocarbonyl group in phosphonodithioformates and phosphonodithioacetates makes these difunctional compounds very versatile building blocks. Moreover, for the phosphonodithioacetates, the substitution of the methylenic hydrogen atoms by fluorine increases again their potential as intermediates for the synthesis of modified natural and bioactive phosphorylated structures. 

Olefins having a-methylenic hydrogens, e.g., octene-1, propylene, and isobutylene, polymerize with difficulty in the presence of free... 

Rhodium carboxylates have been found to be effective catalysts for intramolecular C—H insertion reactions of a-diazo ketones and esters.215 In flexible systems, five-membered rings are formed in preference to six-membered ones. Insertion into methine hydrogen is preferred to a methylene hydrogen. Intramolecular insertion can be competitive with intramolecular addition. Product ratios can to some extent be controlled by the specific rhodium catalyst that is used.216 In the example shown, insertion is the exclusive reaction with Rh2(02CC4F9)4, whereas only addition occurs with Rh2(caprolactamate)4, which indicates that the more electrophilic carbenoids favor insertion. 

The last reaction perhaps involves an intermediate such as 33a which expells a proton and dimethyl sulfide. Formation of the Schiff s base with t-butylamine, reduction with sodium borohydride and hydrogenolysis of the benzyl ether produces sulfonterol (28). Despite the fact that the methylene hydrogen of sulfonterol must be much less acidic than of the corresponding urea proton on carbuterol or the sulfonamide proton on soterenol, good bioactivity is retained. 

Several mechanisms have been postulated in order to account for ketone-sensitized photodehydrochlorination. Benzophenone and acetophenone have been suggested to act as singlet sensitizers via a collisional deactivation process (13). An alternative mechanism proposed for benzophenone involves abstraction of a methylene hydrogen from PVC by the triplet ketone (Equation 2), followed by 3 scission of a... 

The substitution of the exo-methylene hydrogen atoms of MCP with halogens seems to favor the [2 + 2] cycloaddition reaction by stabilizing the intermediate diradical. Indeed, chloromethylenecyclopropane (96) reacts with acrylonitrile (519) to give a diastereomeric mixture of spirohexanes in good yield (Table 41, entry 2) [27], but was unreactive towards styrene and ds-stilbene. Anyway, it reacted with dienes (2,3-dimethylbutadiene, cyclopentadiene, cyc-lohexadiene, furan) exclusively in a [4 + 2] fashion (see Sect. 2.1.1) [27], while its... 

Why does C4H8 adopt puckered D2d geometry As shown in Fig. 3.82, the skeletal carbon atoms twist out of planarity (with dihedral cccc = 17.9°), allowing each methylenic hydrogen to be distinguished as axial (with cccH(a) = 94.9°) or equatorial (with cccH(e) = 138.7°). The puckered equilibrium structure lies only 0.8 kcal mol-1 below the transition-state D4h structure. 

The reaction proceeds via electrogenerated cationic species as its seen with the nonfluorinated amines, carbamates, and amides (Scheme 6.14). However, the regiochemistry of this anodic methoxylation is not governed by the stability of the cationic intermediates B and B (thermodynamic control) since the main products are formed via the less stable intermediates B. Indeed, this remarkable promotion effect and unique regioselectivity can be explained mainly in terms of a-CH kinetic acidities of the cation radicals formed by one-electron oxidation of the amines since the stronger the acidity of the methylene hydrogen, the easier the deprotonation. 

Thus, the substituted tetrazoles 113 upon oxidation with lead tetraacetate gave rise to the fused tetrazoles 114, in most cases in high yields. Tetrazole derivatives 115, bearing an anisidine side chain, also underwent oxidative cyclization and afforded 10-methoxycarbonylmethyltetrazolo[l,5- ]quinoxaline 116 in good yield. This compound was obtained as a mixture of tautomers (with participation of the methylene hydrogen atoms) and the depicted tautomeric form 116 proved to be dominant. 

The relevant interaction diagrams for the Cee and Css conformations are shown in Fig. 27. Arguing as before, we conclude that the Cee conformation will be preferred over the Cse and Css conformations due to an attractive interaction between the out of plane methylene hydrogens. 

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