1,4-bis[2,2-bis(trimethylsilyl)ethenyl]benzene: Regioselective ring opening of its α,β-epoxybis(silane) with some nucleophiles

The Peterson olefination reaction of terephthalaldehyde with tris(trimethylsilyl)methyllithium, (Me₃Si)₃CLi, in Et₂O gives disubstituted vinylbis(silane) 1 which reacts with MCPBA in CH₂Cl₂ at r.t. to afford mixture of mono and disubstituted epoxybis(silanes) 3 and 2. Vinylbis(silane) 1 can be completely converted into epoxybis(silane) 2 with an excess amount of MCPBA. The compound 2 was reacted with various reagents such as HX (X = Cl, Br), H₂SO₄, LiAlH₄ and MeLi/CuI and give the related products.     

取代环戊二烯基锂芳酰化的研究

本文研究了由616-二烷基富烯与有机锂所制得取代环戊二烯基锂和芳酰氯的反应,合成了二十个未见文献报道的新富烯类化合物,并通过^1HNMR、IR和元素分析确定了它们的结构.     

A Theoretical Study of Some Possible Fluxional Pathways for Alkyllithium Hexamers

We examined several possible fluxional pathways for hexameric alkyllithiums, performing ab initio SCF calculations on the model compounds octahedral Li₆H₆, Li₆H₄(CH₃)₂, and Li₆(CH₃)₆. The lowest energy structures for these compounds had an approximately octahedral arrangement of the lithiums, with the H or CH₃ ligands occupying six of the eight faces. The two empty faces were trans related. A concerted mechanism in which each of two ligands on opposite sides of the octahedron moves to an empty face was found to have a low energy barrier. The midpoint structures of this pathway for both Li₆H₆ and Li₆H₄(CH₃)₂ were symmetric or undistorted, whereas the midpoint structure for Li₆(CH₃)₆ was quite distorted. These results are discussed in the light of similar findings on Li₆ clusters. The adequacy of using 3-21G as a basis set for investigating alkyllithium geometries is also discussed.B. Davis Schwartz Memorial Library     

Synthesis and transformations of 3-acetylpyridine-2(1<Emphasis Type="Italic">H</Emphasis>)-thiones

Reactions of substituted 3-cyanopyridine-2(1H)-thiones with methyllithium gave 3-acetylpyridine-2(1H)-thiones. The best results were achieved by adding a solid-state thione to a solution of methyllithium in ether (thione: MeLi = 1: 3). The compounds obtained and their 3-pentanoyl analogs were used to synthesize a number of fused heterocyclic systems. Published in Russian in Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 7, pp. 1504–1507, July, 2008.     

Tris(dimethylsilyl)methyllithium: A Reagent for the Synthesis of Vinylbis(silanes) Containing Si–H Functional Groups

Reactions between a series of nonenolisable aldehydes and tris(dimethylsilyl)methyllithium, (HMe₂Si)₃CLi, are described. The Peterson reaction takes place readily to give vinylbis(silanes). Moreover, styrene and butyl acrylate 1:1 copolymer (P), prepared by use of α,α′-azobis(isobutyronitrile) (AIBN) as an initiator in toluene at 70 ± 1°C, was formylated via direct electophilic substitution by methyl dichloromethyl ether (Cl₂CHOMe) in the presence of tin(IV) chloride (SnCl₄) in nitrobenzene (PhNO₂) as solvent. The reaction of (HMe₂Si)₃CLi with formyl groups on the side chains of the copolymer led to new macromolecules bearing vinylbis(silane) functional groups.     

Condensation of 2-Pyridylmethyllithium Nucleophiles and Pyridine Electrophiles as a Convenient Synthetic Route to Polydentate Chelating N-Donor Ligands

Condensation of 2-pyridylmethyllithium or (6-methyl-2-pyridyl)methyllithium nucleophiles and pyridine, 2-picoline, or 4-tert-butylpyridine as electrophiles leads to new polydentate N-donor ligands, methyl-, tert-butyl-substituted tripyridinedimethanes, or to tripyridinedimethane itself, in good or high yields. Depending on the reagent ratio, solvent used, and reaction conditions, the corresponding intermediate dipyridinemethanes can be minor by-product or major products of the condensation. In contrast to 2-pyridylmethyllithium, lithiated 2-isopropylpyridine does not react with pyridine electrophiles. Vice versa, nucleophilic substitution at the C(2)-pyridine carbon of 2,2-bis(2-pyridyl)propane with 2-pyridylmethyllithium takes place to produce products of condensation of 2-isopropylpyridine and dipyridylmethyllithium. DFT calculations of the Gibbs free energies of reactions combined with pK _a values of the CH-acids involved help to explain the reactivity observed.     

A theoretical study of some possible alkyllithium hexamers

Using ab initio SCF calculations we optimized three possible structures of hexameric methyllithium each having a near octahedral geometry of lithium atoms with capping methyl groups. The isomer in which the vacant faces of the octahedron are trans to each other is the most stable. The alternative structure with the vacant faces in apical contact is 8.8 kcal/mol (6-31G^*//4-31G) higher in energy while the edge contact isomer is 26.3 kcal/mol more energetic than the trans structure. The methyl groups were found not to be faced centered. These results are rationalized electrostatically.     

Organolithium Displacement of Aryl Anions from Tertiary Phosphine Derivatives of Diphenyl Ether

Abstract

Methyllithium displaces a phenyl anion from 10-phenyl-10H-phenoxaphosphine to produce a 70:30 mixture of 10-methyl-10H-phenoxaphosphine and starting phosphine. Butyllithium gives 50% conversion to 10-butyl-10H-phenoxaphosphine. These reactions could take place either by a one-step nucleophilic displacement or by ring cleavage followed by recyclization. To show the feasibility of the two-step process, non-heterocyclic lithiated tertiary phosphines were generated and shown to cyclize to phenoxaphosphines. For example, reaction of 2-phenoxyphenyldiphenylphosphine with phenyllithium produced 10-phenyl-10H-phenoxaphosphine (by lithiation ortho to oxygen followed by cyclization) along with triphenylphosphine (by direct displacement of 2-lithiodiphenyl ether). Other compounds prepared in this work: 2,2′-bis(diphenylphosphino)-diphenyl ether, bis(2-phenoxyphenyl)phenylphosphine, tris(2-phenoxyphenyl)phosphine, 4-carboxy-10-phenyl-10H-phenoxaphosphine, and the oxides and sulfides of the phosphines.