89121-80-2

Upstream product

• 1779-51-7 n-butyl(triphenyl)phosphonium bromide 
• 100-52-7 benzaldehyde 

Downstream Products

• 89121-74-4 (3R,4S)-2,2,2,4-Tetraphenyl-3-propyl-2λ⁵-[1,2]oxaphosphetane 
• 7642-18-4 (Z)-pent-1-en-1-ylbenzene 
• 16002-93-0 (E)-1-phenyl-1-pentene 
• 100-52-7 benzaldehyde 
• 791-28-6 Triphenylphosphine oxide 
• 1560-09-4 (Z)-but-1-en-1-ylbenzene 
• 1005-64-7 trans-1-phenyl-1-butene 
• 14670-41-8 (Z)-1-chloro-4-(pent-1-en-1-yl)benzene 
• 18654-74-5 (E)-1-chloro-4-(pent-1-en-1-yl)benzene 
• 7642-14-0 (Z)-1-(p-chlorophenyl)-1-butene 
• 89121-77-7 (3R,4R)-2,2,2,4-Tetraphenyl-3-propyl-2λ⁵-[1,2]oxaphosphetane 

Relevant academic research and scientific papers

DELVING INTO THE WITTIG REACTION - STEREOCHEMISTRY AND MECHANISM. STEREOCHEMICAL IDIOSYNCRASIES AND MECHANISTIC IMPLICATIONS

Non-stabilized triphenylphosphorus ylides bearing anionic groups can react with aldehydes to give alkene mixtures anomalously enriched in the E isomer .To explain this phenomenon, we sought to study both cis and trans oxaphosphetane (OP) intermediates at low temperature.The observation of both intermediates was achieved for the first time by the use of high-field H-1, P-31, and C-13 NMR spectroscopy in various instances.We have monitored some Wittig reactions in detail via NMR-based kinetic measurements of OP's and alkenes.In certain cases, OP's equilibrate, presumably by reaction reversal to aldehyde and ylide, to introduce a measure of thermodynamic control into the Wittig reaction.Thermodynamic control accounts for a large portion of the excess E stereoselectivity observed in going from a triphenyl to trialkyl (i.e., butyl) phosphorus ylide.Quenching experiments with HBr and the deprotonation of erythro and threo beta-hydroxyphosphonium salts are also discussed.Attempts to investigate reactions of stabilized and semi-stabilized ylides in an analogous manner were not fruitful.

Dramatic Concentration Depedence of Stereochemistry in the Wittig Reaction. Examination of the Lithium Salt Effect

The stereochemistry for Wittig reactions of butylidenetriphenylphosphorane (1) with benzaldehyde and hexanal was examined in detail with regard to concentration effects.For the reaction of 1 and benzaldehyde in the presence of LiBr, the proportion of trans-oxaphosphetane (measured by low-temperature 31P NMR) and (E)-alkene increased with respect to increasing reaction concentration in THF, approaching limiting values in a hyperbolic manner.Stereochemical drift, i.e., exaggerated production of (E)-alkene relative to trans-oxaphosphetane intermediate, was also concentration dependent, being more pronounced at higher concentrations.Experiments with varying amounts of lithium cation, and with NaBr instead of LiBr, demonstrated that this phenomenon is associated with the concentration of Li ion, which is increasingly sequestered by the THF solvent at higher dilution.In Me2SO, the dependence of alkene stereochemistry on concentration was greatly attenuated.In toluene, the concentration effect was inverted to some extent; more (E)-alkene was formed at higher dilution ( no betaines were observed by 31P NMR at low temperature).The reaction of 1 with hexanal in THF, in the presence of LiBr, exhibited a concentration depedence similar to that observed for the reaction with benzaldehyde ( at the oxaphosphetane stage).The rates of the lithium-dependent ("catalyzed") and lithium-independent ("uncatalyzed") reactions in the original carbon-carbon bond-forming step are ranked relative to each other, based on their concentration dependence in THF.For 1 and benzaldehyde in THF (with LiBr present), the catalyzed (k'') and uncatalyzed (k') rates constant have the following relative order: k1'' = 5.2 and k2'' = 2.5 mol-2*dm6*s-1; k1' = 1.0 and k2' -1*dm3*s-1 (see Scheme I and Appendix).Thus, at the representative concentrations of 0.05, 0.20, and 0.50 M, the original carbon-carbon bond-forming step in this Wittig reaction is 27percent, 61percent, and 79percent lithium catalyzed, respectively.