Terminal alkynes deprotonations

Now let s draw the forward scheme. The starting material, -l,ll-dibromo-l-undecene, is treated with sodium acetylide to produce a terminal alkyne. Deprotonation with sodium amide, followed by treatment with a second equivalent of -l,ll-dibromo-l-undecene gives the internal alkyne. Reduction of the alkyne with H2 and Lindlar s catalyst affords the cis alkene. Further treatment with two equivalents of magnesium yields the bis-vinyl Grignard, which reacts with two equivalents of the aldehyde. Aqueous workup produces the target molecule, duryne. 

Acetylene and terminal alkynes are CH-acidic compounds the proton at the carbon-carbon triple bond can be abstracted by a suitable base. Such a deprotonation is the initial step of the Glaser reaction as well as the Eglinton... 

There are a number of procedures for coupling of terminal alkynes with halides and sulfonates, a reaction that is known as the Sonogashira reaction.161 A combination of Pd(PPh3)4 and Cu(I) effects coupling of terminal alkynes with vinyl or aryl halides.162 The reaction can be carried out directly with the alkyne, using amines for deprotonation. The alkyne is presumably converted to the copper acetylide, and the halide reacts with Pd(0) by oxidative addition. Transfer of the acetylide group to Pd results in reductive elimination and formation of the observed product. 

Under basic conditions, obviously only one isomerization step takes place and thus a terminal alkyne will deliver 1,2-dienes selectively. With internal alkynes, on the other hand, selectivity can only be achieved when the alkyne is either symmetrical as in 14 [34] (Scheme 1.6) or has a tertiary center on one side as in 16 [35, 36] (Scheme 1.7). So, unlike potassium 3-aminopropylamide in 1,3-diaminopropane, where the Jt-bonds can migrate over a long distance by a sequence of deprotonations and reprotonations, here the stoichiometric deprotonation delivers one specific anion which is then reprotonated (in 16 after transmetalation). 

Terminal alkynes are usually deprotonated by allylic organozinc reagents but in such cases the triple bond becomes activated towards further addition. Such reactions will be treated in a separate section (see Section III.F). 

Terminal alkynes are readily deprotonated by Grignard reagents, and no further addition occurs to al-kynylmagnesium halides. In the presence of transition metal complexes of titanium,70 iron,70 rhodium,71 nickel,70 72 palladium70 or copper,73 the carbomagnesiation takes place in moderate yields. The regio- and stereo-selectivity of the additions are variable. In the presence of a copper(I) salt, however, only the syn... 

In 1999, Carreira identified Zn(II) as a metal that, like Ag(I) and Cu(I), is capable of effecting the metalation of terminal acetylenes under mild conditions. Thus, treatment of terminal alkynes with Zn(OTf)2 and NEt3 at room temperature led to the formation of zinc alkynylides (Eq. 4). The zinc salt and the amine base work in synergy to weaken the acetylenic proton, with the acetylene undergoing complexation to the Zn(II) center and the base effecting subsequent deprotonation (Fig. 1) [11]. 

Neutral alkynylcopper compounds are not prepared by transmetalation of alkynyllithium compounds. Rather, they are obtained by partially deprotonating terminal alkynes with amines and capturing the ammonium acetylide formed at equilibrium with Cul (—> R-C=C-Cu + R3NH I example Figure 16.7). Copper(I) cyanide couples with aryl iodides and -bromides in a similar fashion as alkynylcopper compounds (which may well be conceived as their carba analogs). 

The cyclo addition of the alkene to the ruthenium vinylidene species leads to a ruthenacyclobutane which rearranges into an allylic ruthenium species resulting from / -elimination or deprotonation assisted by pyridine and produces the diene after reductive elimination (Scheme 16). This mechanism is supported by the stoichiometric C-C bond formation between a terminal alkyne and an olefin, leading to rf-butatrienyl and q2-butadienyl complexes via a ruthenacyclobutane resulting from [2+2] cycloaddition [62]. 

The monosubstituted vinylidene complexes are readily deprotonated with a variety of mild bases (e.g., MeO-, C032 ), and this reaction constitutes the most convenient route to ruthenium acetylide complexes. Experimentally the deprotonation is most easily achieved by passing the vinylidene complex through basic alumina. Addition of a noncomplexing acid (e.g., HPF6) to the acetylide results in the reformation of the vinylidene complex [Eq. (66)]. Reaction of 1 and terminal alkynes such as phenylacetylene in methanol followed by the addition of an excess of... 

Addition of internal alkynes to (t)5-C5H5)(PR3)2RuCI does not lead to the formation of the corresponding disubstituted vinylidene (68). The failure of this reaction could reflect the relative difficulty of a 1,2-alkyl shift for internal alkynes as compared to the 1,2-proton shift for the successful rearrangement of terminal alkynes (Scheme 9). Alternatively, if the deprotonation-reprotonation route is important in the rearrangement of terminal alkynes (vide supra), then clearly internal alkynes would not undergo a similar isomerization. 

Vinyl bromides can themselves be made by elimination reactions of 1,2-dibromoalkanes. Watch what happens when 1,2-dibromopropane is treated with three equivalents of K NLi first, elimination to the vinyl halide then, elimination of the vinyl halide to the alkyne. The terminal alkyne is amply acidic enough to be deprotonated by R2NU, and this is the role of the third equivalent. Overall, the reaction makes a lithiated alkyne (ready for further reactions) from a fully saturated starting material. This may well be the first reaction you have met that makes an alkyne from a starling material that doesn t already contain a triple bond, making an alkyne from 1,2-dibromopropane... 

Very strong bases ( NFL) can deprotonate terminal alkynes. 

Several groups have completed computational studies on the relative stabilities of osmium carbyne, carbene, and vinylidene species. DFT calculations on the relative thermodynamic stability of the possible products from the reaction of OsH3Cl(PTr3)2 with a vinyl ether CH2=CH(OR) showed that the carbyne was favored. Ab initio calculations indicate that the vinylidene complex [CpOs(=C=CHR)L]+ is more stable than the acetylide, CpOs(-C=CR)L, or acetylene, [CpOs() -HC=CR)L]+, complexes but it doesn t form from these complexes spontaneously. The unsaturated osmium center in [CpOsL]+ oxidatively adds terminal alkynes to give [CpOsH(-C=CR)L]+. Deprotonation of the metal followed by protonation of the acetylide ligand gives the vinylidene product. 

Where do hydrocarbons lie on the acidity scale As the data in Table 8.1 show, both methane (pKg == 60) and ethylene (pX = 44) are very weak acids and thus do not react with any of the common bases. Acetylene, however, has pK = 25 and can be deprotonated by the conjugate base of any acid whose pK is greater than 25. Amide ion (NH2 ), foi example, the conjugate base of ammonia (pKj. = 35), is often used to deprotonate terminal alkynes. 

Why is this reaction useful The acetylide anions formed by deprotonating terminal alkynes are strong nucleophiles that can react with a variety of electrophiles, as shown in Section 11.11. 

For terminal alkynes it has been demonstrated [184] that direct proton reduction in DMSO (Pt cathode) leading to the anion is possible. When carried out in the presence of dialkyl ketones, nucleophilic attack leads to alkynylation of the ketone in high current yields (up to 1000%), since the alcoholate is able to deprotonate another alkyne molecule [184]. 

A more general method for arylation of terminal alkynes as well as electron-deficient alkynes is the Negishi Pd-catalyzed cross-coupling of aryl halides with alkynyl-zinc reagents. When using functionally substituted alkynylzincs, the deprotonation of 1-alkynes must be done with LDA instead of alkylithiums. 

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