Of phenyllithium

Carbanions ia the form of phenyllithium, sodium naphthalene complex, sodium acetyHde, or aromatic Grignard reagents react with alkyl sulfates to give a C-alkyl product (30—33). Grignard reagents require two moles of dimethyl sulfate for complete reaction. 

N-protonation the absolute magnitude of the Ad values is larger than for Af-methylation <770MR(9)53>. Nuclear relaxation rates of and have been measured as a function of temperature for neat liquid pyridazine, and nuclear Overhauser enhancement has been used to separate the dipolar and spin rotational contributions to relaxation. Dipolar relaxation rates have been combined with quadrupole relaxation rates to determine rotational correlation times for motion about each principal molecular axis (78MI21200). NMR analysis has been used to determine the structure of phenyllithium-pyridazine adducts and of the corresponding dihydropyridazines obtained by hydrolysis of the adducts <78RTC116>. 

The addition of phenyllithium to 6-arylpyridazin-3(2Er)-one takes place at position 6 to give 6-aryl-3-oxo-6-phenyl-l,2,3,4-tetrahydropyridazine and the reaction of 6-aryl-2,4-diphenylpyridazin-3(2H)-one with phenyllithium or phenylmagnesium bromide affords 6-aryl-2,3,4,6-pentaphenyl-l,2,3,4-tetrahydropyridazine (80S457). 

In the case of phenyllithium, it has been possible to demonstrate by NMR studies that the compound is tetrameric in 1 2 ether-cyclohexane but dimeric in 1 9 TMEDA-cyclohexane. X-ray crystal structure determinations have been done on both dimeric and tetrameric structures. A dimeric structure crystallizes from hexane containing TMEDA. This structure is shown in Fig. 7.1 A. A tetrameric structure incorporating four ether molecules forms from ether-hexane solution. This structure is shown in Fig. 7.IB. There is a good correspondence between the structures that crystallize and those indicated by the NMR studies. 

The reaction of phenyllithium and alfyl chloride labeled with C reveals that allylic rearrangement occurs. About three-fourths of the product results from bond formation at C-3 rather than C-1. This can be accounted for by a cyclic transition state. ... 

The first clearly authenticated preparation of an isoindole was reported by Wittig et in 1951. It was found that elimination from isoindolinium bromides and iodides with bases such as aryl- and alkyllithium afforded 2-substituted isoindoles in variable yields. For instance, 2,2-dimethylisoindolinium bromide (5) on treatment with one equivalent of phenyllithium in ether under nitrogen, evolved methane and gave 2-mcthylisoindole (6) in 74% yield. With methyl-lithium as base, a slightly lower yield was obtained. 

The reaction is carried out in a manner similar to that described above (Chapter 11, Section II). In a 250-ml flask fitted with stirrer, condenser, and dropping funnel is placed a solution of 19.25 g (0.0505 mole) of the phosphonium salt in 180 ml of THF. The nitrogen atmosphere is established and 0.05 mole of phenyllithium added (as a solution in benzene, available from Foote Mineral Co.). The mixture is stirred for 45 minutes at room temperature and then refluxed for 15 minutes. To the red-brown solution is added dropwise over 20 minutes 4.91 g (0.05 mole) of distilled cyclohexanone stirring is continued for 24 hours. The mixture is then concentrated by distillation at... 

Following the procedure given above, cyclopropylidenecyclopentane is prepared in 85% yield from 34.4 g (0.09 mole) of the phosphonium salt, 3.83 g (0.097 mole) of sodium amide (used instead of phenyllithium), and 8.4 g (0.1 mole) of cyclopentanone in ether as solvent (350 ml). The product has bp 69-70770 mm. 

Treatment, in situ, of the unstable 7V-acetyl-2,2 -bis(bromomethyl)diphenylamine (36b) with an excess of phenyllithium yields mainly 5-acetyl-10,l l-dihydro-5//-dibenz[6,/]azepine... 

The first example of asymmetric catalytic ring-opening of epoxides with sp2-hybridized carbon-centered nucleophiles was reported by Oguni, who demonstrated that phenyllithium and a chiral Schiff base ligand undergo reaction to form a stable system that can be used to catalyze the enantioselective addition of phenyllithium to meso-epoxides (Scheme 7.24) [48]. Oguni proposed that phenyllithium... 

The lower diastereoselectivity found with aldehyde 15 (R = CH3) can be explained by the steric influence of the two methyl substituents in close vicinity to the stereogenic center, which probably diminishes the ability of the ether oxygen to coordinate. In contrast, a significant difference in the diastereoselectivity was found in the additions of phenyllithium and phenylmagnesium bromide to isopropylidene glyceraldehyde (17)58 (see also Section 1.3.1.3.6.). Presumably the diastereo-sclcctivity of the phenyllithium addition is determined by the ratio of chelation-controlled to nonchelation-controlled attack of the nucleophile, whereas in the case of phenylmagnesium bromide additional chelation with the / -ether oxygen may occur. Formation of the -chelate 19 stabilizes the Felkin-Anh transition state and therefore increases the proportion of the anZz -diastereomeric addition product. 

The addition of phenyllithium to 3-hydroxy-l,3-diphenyl-1-butanone (4. R1 = R3 = C6HS R2 = H) leads to the predominant formation of either one or the other diastereomer, depending on the reaction temperature146. Thus, for this type of addition reaction there are at least two competing mechanisms which have quite different activation entropies147. 

The highest ee s reported to date for the addition of achiral organometallic reagents in the presence of aprotic chiral additives were observed with the C2-symmetric diamines 10, 11 and 12 (Table 25)13 — 15. Enantioselectivities as high as 89% ee were observed with chiral auxiliary 1012. Addition of phenyllithium to pentanal proceeds with lower enantioselection that the analogous addition of butyllithium to benzaldehydeu. Generally, the enantioselcctivity in-... 

The yield of phenyllithium is approximately 75 per cent. It can be determined by allowing the phenyllithium to react with an excess of benzophenone and weighing the triphenylcarbinol formed. It is assumed that the carbinol is formed quantitatively.1... 

We examined the possibility of a direct formation of two C-C bonds by reaction of a carbanion with [Fe(arene)2]2+ in which the arene bears methyl groups. We could indeed repeat Hellings s experiments but found that mesitylene was the only aromatic allowing this possibility in reasonable yields. With p-xylene, a low yield of an unstable complex was obtained corresponding to double nucleophilic attack of phenyllithium on the same ring in spite of the bulk of the methyl groups [23]. Eq. (4) ... 

All vapourisation processes of solutions made of unstable substances are dangerous because the concentration of the unstable substance increases. In this category the heterogeneous reactions can be grouped together they lead to accidents because of compounds with too thin a particle size distribution. So it is possible to control the reaction of phenyllithium by using thick pieces of lithium. 

In Step H-7 the addition of phenyllithium to the cyclic carbonate group neatly generates the C(2) benzoate group. A similar reaction was used in several other Taxol syntheses. 

Invariably, l,l -diheteroferrocenes (23) have been prepared from the corresponding 1-phenylheteroles (21). The reaction of 21 with lithium in THF (Scheme 1) affords a solution of phenyllithium and the lithium heterocyclopentadienide 22. After the phenyllithium is removed by reac-... 

In a modified preparation of phenyllithium, bromobenzene was added to finely powdered lithium (rather than coarse particles) in ether. The reaction appeared to be proceeding normally, but after about 30 min it became very vigorous and accelerated to explosion. It was thought that the powdered metal may have been partially coated with oxide or nitride which abraded during stirring, exposing a lot of fresh metal surface on the powdered metal. 

No pure product has been isolated from the reaction of four molar equivalents of C6H5Li with [(Cl6H5)2C=NBBr2]2 471. It is possible that this event is due to the use of an ethereal solution of phenyllithium, the ether being cleaved by the >BBr2 groups. 

Reduction of the triboracyclobutane 11a, (Scheme 3.2-7), the 1,2,4-triboracyclo-pentane 86a, and the 1,3,5-triboracyclohexane 87 with elemental Li gives the lithium salts of the corresponding dianions 10a2, 86a2- and 872-, respectively [20, 22, 102], The dianion 86b2- is obtained by addition of phenyllithium to the anion of 12b (Scheme 3.2-43) [44],... 

Hindered aliphatic aldehydes R CIIO (R1 = i-Pr or i-Bu) react with benzotriazole and anhydrous methanolic ammonia to yield the secondary amines 115, which are transformed into the phenylated amines 116 by the action of phenyllithium. Benzotriazole, aromatic aldehydes and ammonia give the imines 117, which react with lithium aluminium hydride to form dibenzylamines 118122. 

Nucleophilic acyl complexes can be 0-alkylated with hard electrophiles to yield the corresponding alkoxy- or (acyloxy)carbene complexes. The first carbene complex ever isolated [61] was prepared by this route the intermediate, anionic acyl complex was generated by addition of phenyllithium to tungsten hexacarbonyl (Figure 2.3). 

So far, only cuprates with a 1 1 copper/lithium ratio have been considered. Treatment of phenyllithium with various substoichiometric quantities of copper bromide in DMS as solvent afforded so-called higher order cuprates, of which two were characterizable by X-ray crystallography. These have the overall stoichiometries Cu2Li3Ph5(DMS)4 and Cu4Li5Ph9(DMS)4 [114, 115). The structure of the former compound in the solid state is shown in Fig. 1.26. 

This preparation is based on a procedure published by the submitters. 9-Phenylphenanthrene has been prepared previously by the reaction of phenyllithium with 9-chlorophelianthrene, by the high-temperature dehydrogenation with palladimn on charcoal of the Diels-Alder dimer of 1-phenyl-1,3-butadiene, and by the acid-catalyzed cyclization of the alcohol formed from the reaction of 2-biphenylylmagnesium iodide and 2-phenoxy-acetophenone. ... 

Some unexpected reactions are observed during the interaction of cyclo-hepta[c]thien-6-one (231) or its 1,3-dibromo derivative and organometallic compounds (74YZ1429) These reactions are halogen-metal interconversion and subsequent dimerization, partial debromination, and simultaneous 1,2- and 1,4-addition of phenyllithium onto tropone 231 to yield tropylium salts 232 and 233, respectively (Scheme 56). 

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