Lithium butoxide catalyst

Following a procedure similar to Dileone s, we have reacted diepoxides, including BADGE, with MDI. The catalysts used were lithium butoxide and tetraethylammonium bromide. Products were isolated by additions to the DMF solution of first water and then, in some reactions, methanol. 

We have further examined the effect of initiators and solvents on the equilibrium product distribution. The use of lithium tert-butoxide instead of potassium tert-butoxide and the change of solvent from THF to toluene showed no effect on the product distribution of e-caprolactone oligomers.4 Also we are examining the equilibrium oligomer distribution in cationic system such as trifluoromethane sulfonic acid catalyst.z... 

An equimolar mixture of 3,4,5-trimethoxy phenyl iodide 157, lithium propargyl alkoxide 158, and diethyl ethoxymethylene malonate 159 was stirred at room temperature in the presence of a palladium catalyst. Then, to the resulting intermediate 161 potassium t-butoxide was added, and the ensuing base-promoted decarboxylative aromatization afforded tetrahydrofuran MCR adduct 162 in good yield. The ester was first reduced and the furan ring was hydrogenated with Raney nickel to furnish a diastereomeric mixture of products 163 in high yield. Further synthetic manipulations then provided a known precursor to the natural product. 

DIENES Dichloromalcic anhydride. DITERPENES Palladium catalysts. OLEFINS Cuprous chloride. Lithium di-phenylphosphide. Lithium orthophosphate. Potassium r-butoxide. Thiophe-nol-Azobuty toni tide. OXASPIROPENTANE Lithium iodide. 

Color reactions Boric acid (hydroxyquinones). Dimethylaminobenzaldehyde (pyrroles). Ferric chloride (enols, phenols). Haloform test. Phenylhydrazine (Porter-Silber reaction). Sulfoacetic acid (Liebermann-Burchard test). Tetranitromethane (unsaturation). Condensation catalysts /3-Alanine. Ammonium acetate (formate). Ammonium nitrate. Benzyltrimethylammonium chloride. Boric acid. Boron trilluoride. Calcium hydride. Cesium fluoride. Glycine. Ion-exchange resins. Lead oxide. Lithium amide. Mercuric cyanide. 3-Methyl-l-ethyl-2-phosphoiene-l-oxlde. 3-Methyl-1-phenyi-3-phoipholene-1-oxide. Oxalic acid. Perchloric acid. Piperidine. Potaiaium r-butoxIde. Potassium fluoride. Potassium... 

Most alkylidenecyclopropanes have been prepared by reacting cyclopropylidenetriphenyl-.i -phosphane with aldehydes and ketones. The phosphorus ylide is either prepared by treating cyclopropyltriphenylphosphonium bromide, a stable compound, with base, e.g. phenyl-lithium, potassium er/-butoxide, sodium hydride, or by generating both the phos-phonium salt and the ylide in situ from (3-bromopropyl)triphenylphosphonium bromide employing two equivalents of base. ° The latter method seems to give somewhat better yields, as indicated by the synthesis of l-diphenylmethylene-2-methylcyclopropane (1) from ben-zophenone. ° The yield has also been increased by adding a catalyst. Considerable improvements have in particular been observed by using tris[2-(2-methoxyethoxy)ethyl]amine, a phase-transfer catalyst, e.g. formation of The use of several phosphorus ylides and bases is summarized in Table 25. 

Shibasaki s heterobimetallic complexes, active in the asymmetric aldol reaction (see Section 7.1) provide the opportunity to activate both the nucleophile and Michael acceptor. Whilst the aluminium lithium bis-BlNOL complex (ALB) (11.28) does not catalyse conjugate addition of a-phosphonate ester (11.29) with cyclopentenone (11.30) by itself, addition of sodium terf-butoxide allows a highly enantioselective reaction to take place. A postulated model for enantioinduction in this process involves simultaneous binding of the metallated nucleophile and acceptor to the catalyst by interaction with a BINAP oxygen and the aluminium centre respectively. Heterobimetallic complexes have also been used to catalyse the addition of a-nitroesters and malonatesto Michael acceptors. 

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