Alkynes iodination

A more successful approach is found in the addition of iodine or bromine azide to alkynes . Iodine azide has been found to add... 

To demonstrate the versatility of this process and to provide a relevant model study for the synthesis of 1, we investigated an extension to medium-sized heterocycles. Thus, the diastereomeric silyl ethers 8a-b were selected to test this application by generation of the corresponding 9-membered oxacyclic dienes (Scheme 3). The preparation of 8a-b began with the reduction of pyruvic aldehyde dimethoxy acetal with NaBH4 in MeOH/THF to afford hydroxy acetal 2 (84%). Alkylation of the sodium salt of 2 with propargylic bromide afforded 3 (85%). Conversion of 3 to 5 was achieved by alkyne iodination followed by a c/s-reduction of... 

Keywords Alkynes, iodine/hydrophosphine binary system, CDCI3, room temperature, regioselective hydroiodination, Markovnikov-type addition, vinyl iodides... 

Cis-olefins or cis./rjns-dienes can be obtained from alkynes in similar reaction sequences. The alkyne is first hydroborated and then treated with alkaline iodine. If the other substituents on boron are alkyl groups, a cis-olefin is formed (G. Zweifel, 1967). If they are cir-alkenyls, a cis, trans-diene results. The reactions are thought to be iodine-assisted migrations of the cis-alkenyl group followed by (rans-deiodoboronation (G. Zweifel, 1968). Trans, trans-dienes are made from haloalkynes and alkynes. These compounds are added one after the other to thexylborane. The alkenyl(l-haloalkenyl)thexylboranes are converted with sodium methoxide into trans, trans-dienes (E. Negishi, 1973). The thexyl group does not migrate. 

The iodination reaction can also be conducted with iodine monochloride in the presence of sodium acetate (240) or iodine in the presence of water or methanolic sodium acetate (241). Under these mild conditions functionalized alkenes can be transformed into the corresponding iodides. AppHcation of B-alkyl-9-BBN derivatives in the chlorination and dark bromination reactions allows better utilization of alkyl groups (235,242). An indirect stereoselective procedure for the conversion of alkynes into (H)-1-ha1o-1-alkenes is based on the mercuration reaction of boronic acids followed by in situ bromination or iodination of the intermediate mercuric salts (243). 

Terminal (perfluoroalkyl)alkynes react with iodine or iodine chloride to yield syn addition products bearing iodine on the terminal carbon [16 (equation 9). 

A valuable feature of the Nin/Crn-mediated Nozaki-Takai-Hiyama-Kishi coupling of vinyl iodides and aldehydes is that the stereochemistry of the vinyl iodide partner is reflected in the allylic alcohol coupling product, at least when disubstituted or trans tri-substituted vinyl iodides are employed.68 It is, therefore, imperative that the trans vinyl iodide stereochemistry in 159 be rigorously defined. Of the various ways in which this objective could be achieved, a regioselective syn addition of the Zr-H bond of Schwartz s reagent (Cp2ZrHCl) to the alkyne function in 165, followed by exposure of the resulting vinylzirconium species to iodine, seemed to constitute a distinctly direct solution to this important problem. Alkyne 165 could conceivably be derived in short order from compound 166, the projected product of an asymmetric crotylboration of achiral aldehyde 168. 

Haloalkynes (R—C=C—X) react with ArSnBu3 and Cul to give R—C= C—Ar. Acetylene reacts with two equivalents of iodobenzene, in the presence of a palladium catalyst and Cul, to give 1,2-diphenylethyne. 1-Trialkylsilyl alkynes react with 1-haloalkynes, in the presence of a CuCl catalyst, to give diynes and with aryl triflates to give 1-aryl alkynes. Alkynes couple with alkyl halides in the presence of Sml2/Sm. Alkynes react with hypervalent iodine compounds " and with reactive alkanes such as adamantane in the presence of AIBN. ... 

Both alkynes and alkenes can be obtained from adducts of terminal alkynes and boranes. Reaction with iodine induces migration and results in the formation of the alkylated alkyne.32... 

It is not normally possible to add fluorine directly to alkenes as the reaction is so exothermic that bond fission occurs. Many alkenes will not add iodine directly either, and when the reaction does occur it is usually readily reversible. Alkynes are also found to undergo preferential, though not exclusive, ANTI addition of halogens, e.g. with butyne-l,2-dioic acid (17) ... 

Steps including hydroxy directed alkyne hydroalumination-iodination... 

Sonogashira reactions of both a-halothiophenes [117] and P-halothiophenes [118] proceed smoothly even for fairly complicated molecules as illustrated by the transformation of brotizolam (134) to alkyne 135 [119]. Interestingly, 3,4-bis(trimethylsilyl)thiophene (137), derived from the intermolecular cyclization of 4-phenylthiazole (136) and bis(trimethylsilyl)acetylene, underwent consecutive iodination and Sonogashira reaction to make 3,4-bisalkynylthiophenes [120], Therefore, a regiospecific mono-i/wo-iodination of 137 gave iodothiophene 138, which was coupled with phenylacetylene to afford alkynylthiophene 139. A second iodination and a Sonogashira reaction then provided the unsymmetrically substituted 3,4-bisalkynylthiophene 140. 

Advantage has been taken of the aforementioned observations in the synthesis of a terthiophene natural product, arctic acid (147) [123]. Pd-catalyzed carbonylation of bromobisthiophene 25, obtained from the Kumada coupling of 2-thienylmagnesium bromide and 2,5-dibromothiophene, gave bithiophene ester 144, which was converted to iodide 145 by reaction with iodine and yellow mercuric oxide. Subsequent propynylation of 145 was then realized using the Sonogashira reaction with prop-l-yne to give bisthienyl alkyne 146, which was subsequently hydrolyzed to 5 -(l-propynyl)-2,2 -bithienyl-5-carboxylic acid (147), a natural product isolated from the root of Arctium lappa. 

Kim and Russell synthesized 5,6-diethynyl-2,4-dimethoxypyrimidine (85) starting from iodination of 5-chloro-2,4-dimethoxypyrimidine [61], Very careful experimentation resulted in optimal conditions for the Sonogashira reaction of dihalopyrimidine 83 with trimethylsilylacetylene to provide bis-alkyne 84. The temperature appeared to be crucial. Only mono-substitution for the iodine was observed at lower temperature, whereas Bergman cyclization seemed to occur at temperatures higher than 120 °C. Subsequent desilylation of 84 then delivered diethynylpyrimidine 85. 

The isomerization of the smallest alkynes 80 with halogens in a propargylic position has been described for chlorine [151, 152], bromine [153] and iodine [154] (Scheme 1.35), but often might proceed by an SN2 -type substitution rather than a prototropic rearrangement [155-159]. On the other hand, transformations such as 82 —> 83 [160] or 84 —> 85 [161] are clearly prototropic (Scheme 1.36). This is also true for propargylic halides such as 86 with its additional ester group assisting the prototropic isomerization [162,163] (Scheme 1.37). 

Terminal alkynes are converted in high yield (70-80%) into 1-iodoalkynes by their copper-catalysed reaction with iodine under phase-transfer catalytic conditions... 

Shortly after this reaction was reported, Hegedus found46 that imines undergo a similar insertion process. The products (251) are structurally very similar to the alkyne adducts (247), and decomplexation with iodine, followed by treatment with trimethylamine TV-oxide, afforded a variety of substituted pyridones in good yield. 

The preparation of vinyl iodide 39 first required the transformation of (E,E)-farnesyl acetone (28), performed according to Negishi, to the terminal alkyne 27 with 75% yield [35]. The latter then gave (E)-vinyl iodide 39 in dia-stereomerically pure form and 74% yield by Zr-catalyzed carboalumination with trimethylaluminum and trapping of the intermediate vinylaluminum species with iodine [36]. The alkyl iodide rac-29 necessary to ensure the coupling with 39 was obtained by selective monofunctionalization of 3-methyl-pentane-1,5-diol (26) in a few steps [37]. 

Regardless of whether the Pd-catalyzed coupling or alkyne metathesis is utilized to make PAEs, the critical step is the synthesis of the diiodoarene monomers. In this section some of the more interesting syntheses are showcased. The synthesis of dipropynyldi-tert-butylnaphthalene is shown in Scheme 5. Starting from naphthalene, Friedel-Crafts alkylation with 2-chloro-2-methylbutane gives a mixture of two di-tert-butylnaphthalenes that are separated by crystallization. Iodination of the correct isomer is followed by a Pd-catalyzed coupling of propyne to the diiodide to give the desired l,5-dipropynyl-3,8-di-tert-butyl-naphthalene [56] ready for ADIMET. 

The heterocyclic PAEs are useful for low-bandgap applications, as n-type semiconductors, and in sensory applications. Again, as long as the alkynylated or iodinated monomers are available, the synthesis of the corresponding PAE is not a problem, and either the Pd-catalyzed couplings or alkyne metathesis can be utilized toward that end. 

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