Alkynes, anions, reaction with

Pentaazadienes, structure, 32 171-172 Pentaborane(9) reaction of with alkynes, 26 74 Pentacarbonyltungstenhydrogen sulfide anion, reaction with hexafluoroacetone, 30 297 Penta-coordinate complexes, 4 175-178 Pentacyanides... 

The real value of this acid-base reaction is to transform a weak acid into an anion by using a powerful base the organolithium reagent. Such anions behave as nucleophiles in various reactions. In Chapter 11 (Section 11.3.6), alkyne anions underwent Sn2 reactions with alkyl halides. In Chapter 18 (Section 18.3.2), alkyne anions react with aldehydes and ketones. Both Grignard reagents and organolithium reagents react as nucleophiles with aldehydes and ketones (also described in Chapter 18, Section 18.4). Lithium amides such as 45 react as bases with aldehydes or ketones in Chapter 22 (Section 22.3). Many such examples are discussed in this book. 

The new functional group exchange reactions presented in this chapter can be combined with reactions from previous chapters to expand the ability to synthesize molecules. Alkene 85 is synthesized from aldehyde 86, for example. The first task is to identify the four carbons of 86 in 85. It appears that the carbons marked in blue are the best candidates. Rather than disconnect the C-C=C unit marked in blue, first disconnect the ethyl group of 85 to give 87 and 88. This choice is made because no reaction has been presented that will allow direct incorporation of EtCHCH to X-C-CMea. Disconnection of the ethyl group takes advantage of the fact that an alkyne anion reacts with an alkyl halide. However, before this reaction can be used, the alkene unit in 87 needs to be changed to an alkyne unit in 89. 

High yields of alkynes can be obtained from the reaction of 1,1-dichloromethyl-lithium with alkyl halides and subsequent dehydro-halogenation. The alkyne anion (40) with alkyl halides gives a-substituted prop-2-ynylamines and with CO2 gives a-acetylenic amino-acids, in good yields. 

Terminal alkynes undergo the above-mentioned substitution reaction with aryl and alkenyl groups to form arylalkynes and enynes in the presence of Cul as described in Section 1.1.2.1. In addition, the insertion of terminal alkynes also takes place in the absence of Cul, and the alkenylpalladium complex 362 is formed as an intermediate, which cannot terminate by itself and must undergo further reactions such as alkene insertion or anion capture. These reactions of terminal alkynes are also treated in this section. 

These compounds are sources of the nucleophilic anion RC=C and their reaction with primary alkyl halides provides an effective synthesis of alkynes (Section 9 6) The nucleophilicity of acetylide anions is also evident m their reactions with aldehydes and ketones which are entirely analogous to those of Grignard and organolithium reagents... 

Alkyne alkylation is not limited to acetylene itself. Any terminal alkyne can be converted into its corresponding anion and then alkylated by treatment with an alkyl halide, yielding an internal alkyne. For example, conversion of 1-hexyne into its anion, followed by reaction with 1-bromobutane, yields 5-decyne. 

Terminal alkynes can be converted readily into alkynylsilanes by reaction of the corresponding alkyne anion or its metalloid equivalent with a suitable chlorosilane (/). The reverse reaction, that of liberation of the alkyne, is quite facile, being effected by several reagent combinations, including hydroxide ion, methanolysis, fluoride anion, silver(i) followed by cyanide anion, and methyl lithium-lithium bromide (2). 

The most convenient pathway to this important class of compounds is the reaction of alkynes RG=GH with salts of the bis(acetylacetonato)gold anion.71 This reaction leads to almost any type of target compounds, including those with R = H, alkyl, alkenyl, alkynyl, aryl, heteroaryl, etc. (Q = metal or quaternary or PPN cation Equation (22)). 

On the basis of these results we embarked on a systematic study on the synthesis of vinyl cations by intramolecular addition of transient silylium ions to C=C-triple bonds using alkynyl substituted disila alkanes 6 as precursors.(35-37) In a hydride transfer reaction with trityl cation the alkynes 6 are transformed into the reactive silylium ions 7. Under essentially nonHnucleophilic reaction conditions, i.e. in the presence of only weakly coordinating anions and using aromatic hydrocarbons as solvents, the preferred reaction channel for cations 7 is the intramolecular addition of the positively charged silicon atom to the C=C triple bond which results in the formation of vinyl cations 8-10 (Scheme 1). 

Acylzirconocene chlorides 78, which are easily available through the hydrozirco-nation of alkenes or alkynes with Cp2Zr(H)Cl and subsequent CO insertion, can be used as acyl anion equivalents Cu(I)-catalyzed reactions with propargyl compounds 77 afford allenyl ketones 79 (Scheme 3.40) [86]. The use of an excess of 77 (2 equiv. to 78) is important for the selective preparation of 79, which prevents an undesirable side reaction of the allenic products 79 with 78. 

CuBr/QUINAP System The CuBr/QUlNAP system was initially used in the enan-tioselective synthesis of proparyl amines via the reaction of alkynes and enamines (Scheme 5.5). It was rationalized that the enamines reacted with protons in terminal alkynes in the presence of copper catalyst to form zwitterionic intermediates in which both the generated iminiums and alkyne anions coordinate to the copper metal center. After an intermolecular transfer of the alkyne moiety to the iminium ion, the desired products were released and the catalyst was regenerated. The combination of CuBr as catalyst and the chiral ligand QUEMAP is crucial for the good reactivities and enantioselectivities seen in the reaction. Another potential... 

Hull MW, Sevov SC (2007) Addition of alkenes to deltahedral zintl clusters by reaction with alkynes synthesis and stmcture of [Fc-CH=CH-Ge9CH-Fc] an organo-zinti-organometal-lic anion. Angew Chem Int Ed 46 6695-6698... 

Reactions with Protic, ionic, Poiar Reagents. The reactions of radical anions with proton donors include the reduction of arenes, the well-known Birch reduction, as well as alkynes by alkali metals in liquid ammonia. Both reactions have synthetic utility and belong to the few radical ion reactions included in elementary textbooks. 

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