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Terminal alkynes, base

There also exists an acidregioselective condensation of the aldol type, namely the Mannich reaction (B. Reichert, 1959 H. Hellmann, 1960 see also p. 291f.). The condensation of secondary amines with aldehydes yields Immonium salts, which react with ketones to give 3-amino ketones (=Mannich bases). Ketones with two enolizable CHj-groupings may form 1,5-diamino-3-pentanones, but monosubstitution products can always be obtained in high yield. Unsymmetrical ketones react preferentially at the most highly substituted carbon atom. Sterical hindrance can reverse this regioselectivity. Thermal elimination of amines leads to the a,)3-unsaturated ketone. Another efficient pathway to vinyl ketones starts with the addition of terminal alkynes to immonium salts. On mercury(ll) catalyzed hydration the product is converted to the Mannich base (H. Smith, 1964). [Pg.57]

Out first example is 2-hydroxy-2-methyl-3-octanone. 3-Octanone can be purchased, but it would be difficult to differentiate the two activated methylene groups in alkylation and oxidation reactions. Usual syntheses of acyloins are based upon addition of terminal alkynes to ketones (disconnection 1 see p. 52). For syntheses of unsymmetrical 1,2-difunctional compounds it is often advisable to look also for reactive starting materials, which do already contain the right substitution pattern. In the present case it turns out that 3-hydroxy-3-methyl-2-butanone is an inexpensive commercial product. This molecule dictates disconnection 3. Another practical synthesis starts with acetone cyanohydrin and pentylmagnesium bromide (disconnection 2). Many 1,2-difunctional compounds are accessible via oxidation of C—C multiple bonds. In this case the target molecule may be obtained by simple permanganate oxidation of 2-methyl-2-octene, which may be synthesized by Wittig reaction (disconnection 1). [Pg.201]

Alkynes undergo stoichiometric oxidative reactions with Pd(II). A useful reaction is oxidative carboiiyiation. Two types of the oxidative carbonyla-tion of alkynes are known. The first is a synthesis of the alkynic carbox-ylates 524 by oxidative carbonylation of terminal alkynes using PdCN and CuCh in the presence of a base[469], Dropwise addition of alkynes is recommended as a preparative-scale procedure of this reation in order to minimize the oxidative dimerization of alkynes as a competitive reaction[470]. Also efficient carbonylation of terminal alkynes using PdCU, CuCI and LiCi under CO-O2 (1 I) was reported[471]. The reaction has been applied to the synthesis of the carbapenem intermediate 525[472], The steroidal acetylenic ester 526 formed by this reaction undergoes the hydroarylalion of the triple bond (see Chapter 4, Section 1) with aryl iodide and formic acid to give the lactone 527(473],... [Pg.97]

The 2,3-alkadienyl acetate 851 reacts with terminal alkynes to give the 2-alkynyl-1,3-diene derivative 852 without using Cul and a base. In the absence of other reactants, the terminal alkyne 853 is formed by an unusual elimination as an intermediate, which reacts further with 851 to give the dimer 854. Hydrogenolysis of 851 with formic acid affords the 2, 4-diene 855[524]. [Pg.406]

Although acetylene and terminal alkynes are far stronger acids than other hydro carbons we must remember that they are nevertheless very weak acids—much weaker than water and alcohols for example Hydroxide ion is too weak a base to convert acety lene to its anion m meaningful amounts The position of the equilibrium described by the following equation lies overwhelmingly to the left... [Pg.369]

The most frequent applications of these procedures he in the preparation of terminal alkynes Because the terminal alkyne product is acidic enough to transfer a proton to amide anion one equivalent of base m addition to the two equivalents required for dou ble dehydrohalogenation is needed Adding water or acid after the reaction is complete converts the sodium salt to the corresponding alkyne... [Pg.373]

Acetylene and terminal alkynes are more acidic than other hydrocarbons They have s of approximately 26 compared with about 45 for alkenes and about 60 for alkanes Sodium amide is a strong enough base to remove a proton from acetylene or a terminal alkyne but sodium hydroxide is not... [Pg.382]

The acidity of acetylene and terminal alkynes permits them to be converted to their conjugate bases on treatment with sodium amide These anions are good nucleophiles and react with methyl and primary alkyl halides to form carbon-carbon bonds Secondary and tertiary alkyl halides cannot be used because they yield only elimination products under these conditions... [Pg.383]

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... [Pg.135]

The most striking difference between alkenes and alkynes is that terminal alkynes are weakly acidic. When a terminal alkyne is treated with a strong base, such as sodium amide, Na+ -NH2, the terminal hydrogen is removed and an acetylide anion is formed. [Pg.270]

Terminal alkynes are weakly acidic. The alkyne hydrogen can be removed by a strong base such as Na+ NH2 to yield an acetylide anion. An acetylide... [Pg.279]

The present route to (terminal alkynes reported by a group from the Chemical Process Department at the DuPont Pharmaceutical Company.2 This alcohol serves as a convenient starting material for the preparation of 1-acyloxy 4-mesylates 10 (eq 1). [Pg.86]

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. [Pg.87]

In general, strong bases such as NaNH2 convert internal alkynes to terminal alkynes [a particularly good base for this purpose is potassium 3-aminopropyIamide (NH2CH2CH2CH2NHK) ], because the equilibrium is shifted by formation of the... [Pg.771]

Organic compounds can be metalated at suitably acidic positions by active metals and by strong bases.The reaction has been used to study the acidities of very weak acids (see p. 228). The conversion of terminal alkynes to acetylid ions is one... [Pg.793]

Terminal alkynes can be coupled by heating with stoichiometric amounts of cupric salts in pyridine or a similar base. This reaction, which produces symmetrical diynes... [Pg.927]

Thiourea was used as stabilising agent for zerovalent Pd species [117]. The Pd-thiourea (H2NCSNH2) catalysed carbonylation of terminal alkynes and allylic alcohols has been described by Chiusoh [118]. More recently, Pd-thiourea-catalysed carbonylative annulation was studied. The reaction proceeds between alkynes, iodophenol acetates and carbon monoxide, in the presence of dppp, thiourea (H2NCSNH2) and base at 40 °C. Flavones have been obtained in good yields (Scheme 30) [119]. [Pg.251]

Related to these strategies, Fe(OTf)3/TfOH cocatalyzed the coupling reaction of terminal alkynes with benzylic alcohols in the absence of base by means of a sp-sp C-C bond formation (Scheme 16) [32]. [Pg.12]

The stoichiometric insertion of terminal alkenes into the Cu-B bond of the (NHC)Cu-B(cat) complex, and the isolation and full characterisation of the p-boryl-alkyl-copper (I) complex has been reported. The alkyl complex decomposes at higher temperatures by P-H elimination to vinylboronate ester [67]. These data provide experimental evidence for a mechanism involving insertion of alkenes into Cu-boryl bonds, and establish a versatile and inexpensive catalytic system of wide scope for the diboration of alkenes and alkynes based on copper. [Pg.40]

Several methods for stereoselective alkene synthesis are based on boron intermediates. One approach involves alkenylboranes, which can be prepared from terminal alkynes. Procedures have been developed for the synthesis of both Z- and E-alkenes. [Pg.793]

Other ruthenium-based catalysts are also active. Ruthenium dichloride-cymene complex is stereoselective for formation of the Z-vinyl silanes from terminal alkynes. [Pg.812]

See other pages where Terminal alkynes, base is mentioned: [Pg.1330]    [Pg.1332]    [Pg.1332]    [Pg.1330]    [Pg.1087]    [Pg.51]    [Pg.1330]    [Pg.1332]    [Pg.1332]    [Pg.1330]    [Pg.1087]    [Pg.51]    [Pg.169]    [Pg.169]    [Pg.172]    [Pg.206]    [Pg.594]    [Pg.393]    [Pg.410]    [Pg.594]    [Pg.21]    [Pg.410]    [Pg.724]    [Pg.485]    [Pg.798]    [Pg.1189]    [Pg.47]    [Pg.8]    [Pg.205]    [Pg.1256]   
See also in sourсe #XX -- [ Pg.117 ]



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Complexed terminal alkynes, base

Terminal alkynes

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