Propargylic compounds alcohols

Umpolung of propargyl compounds occurs in the presence of excess Et2Zn, and homopropargyl alcohols 187 are obtained by the reaction of propargyl benzoates (186) with benzaldehyde, although the exact mechanism is not known. Ethylallene, which is expected to be formed by transmetallation of the allenylpalladium with Et2Zn and reductive elimination, is not formed [41],... 

Propargylic compounds undergo facile palladium-catalyzed mono- and dicarbonylations, depending on the reaction conditions [9]. The carbonylation of propargylic alcohols has... 

Stereoselective conversion of propargylic compounds to haloallenes normally proceeds with high anti stereoselectivity. On the other hand, syn selectivity is observed for the copper(I) bromide hydrobromide induced conversion of propargylic alcohol into the corresponding 1-bromoallene with low enantiomeric excess (6% ee). The sulfinate ester, however, again gave anti stereoselectivity with moderate enantiomeric excess150. 

The gold(III)-catalyzed direct nucleophilic substitution of allyl or propaigyl alcohols is possible with many nucleophiles, including allyl silanes, electron-rich aromatics, p-dicarbonyl compounds, alcohols, and sulfonamidesJ With thiols, the corresponding propargyl thioethers were obtained with moderate yield (Scheme 4-121). 

Several helical polycyclic aromatic hydrocarbons bearing aryl substituents at the most sterically hindered position were synthesized in an efficient three-step cascade reaction. The initial benzannulated enediynes were synthesized by the reaction of appropriate lithium acetylenides with an aryl-rert-butyl ketone. This was followed by reduction of the resultant acetylenic propargyl type alcohol with triethylsilicon hydride. This method turned out to be particularly successful for the synthesis of helical molecules. The reaction of ketones 3.588 and 3.590 with the lithium derivative of l-ethynyl-2-(2-penylethynyl)benzene 3.545 or related binaphthyl derivative followed by reduction and three-step sequence of cascade reactions led to polycyclic aromatic compounds 3.589 and 3.591, respectively, in a good yield (Scheme 3.48) [294, 295]. 

In addition, propargylic alcohols can generate stabilized carbocations under metal- and organocatalysis conditions. Thus, when used with enolizable aldehydes under these reactions, asymmetric access to the corresponding alkylated propargylic compounds is given [50]. 

Propargylic (or 2-alkynyl) compounds are derivatives of alkynes. However, Pd-catalyzed reactions of propargylic derivatives, particularly esters and halides, are very different mechanistically from those of simple alkynes, except in a few cases. Therefore, the reactions of propargylic esters and halides are treated in this section separately from those of other alkynes. However, some reactions of propargylic alcohols, which behave similarly to simple alkynes, are treated in Section 6. 

Acetylene is condensed with carbonyl compounds to give a wide variety of products, some of which are the substrates for the preparation of families of derivatives. The most commercially significant reaction is the condensation of acetylene with formaldehyde. The reaction does not proceed well with base catalysis which works well with other carbonyl compounds and it was discovered by Reppe (33) that acetylene under pressure (304 kPa (3 atm), or above) reacts smoothly with formaldehyde at 100°C in the presence of a copper acetyUde complex catalyst. The reaction can be controlled to give either propargyl alcohol or butynediol (see Acetylene-DERIVED chemicals). 2-Butyne-l,4-diol, its hydroxyethyl ethers, and propargyl alcohol are used as corrosion inhibitors. 2,3-Dibromo-2-butene-l,4-diol is used as a flame retardant in polyurethane and other polymer systems (see Bromine compounds Elame retardants). 

Compounds with triple bonds, i.e. acetylenic compounds, continue to receive attention. Patents have been filed for mixtures of propargyl alcohol with, for example, cellosolve + a phenol formaldehyde resin + tar bases heterocyclic nitrogen compounds + acetylenic + dialkylthiourea or a quaternary + antimony oxide . 

Previous syntheses of terminal alkynes from aldehydes employed Wittig methodology with phosphonium ylides and phosphonates. 6 7 The DuPont procedure circumvents the use of phosphorus compounds by using lithiated dichloromethane as the source of the terminal carbon. The intermediate lithioalkyne 4 can be quenched with water to provide the terminal alkyne or with various electrophiles, as in the present case, to yield propargylic alcohols, alkynylsilanes, or internal alkynes. Enantioenriched terminal alkynylcarbinols can also be prepared from allylic alcohols by Sharpless epoxidation and subsequent basic elimination of the derived chloro- or bromomethyl epoxide (eq 5). A related method entails Sharpless asymmetric dihydroxylation of an allylic chloride and base treatment of the acetonide derivative.8 In these approaches the product and starting material contain the same number of carbons. 

When X=OH, this conversion of acetylenic alcohols to unsaturated aldehydes or ketones is called the Meyer-Schuster rearrangement The propargyl rearrangement can also go the other way that is, 1-haloalkenes, treated with organocopper compounds, give alkynes. ... 

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