Iodo copper

Other syntheses utilise a-bromo or a-iodo compounds, which condense on heating with copper (44). 

The perfluoroacetylenic copper compounds undergo coupling reactions with aryl iodides and provide a useful synthetic route to the perfluoroalkyl aryl alkynes [147, 255] (equation 170) Coupling of these copper reagents with the 1-iodo-perfluoroalkynes gives the perfluorodiynes [747 255] (equation 171)... 

An organozinc compound that occupies a special niche in organic synthesis is iodo-methylzinc iodide (ICH2ZnI). It is prepared by the reaction of zinc-copper couple [Zn(Cu), zinc that has had its surface activated with a little copper] with diiodomethane in diethyl ether. 

Halothiophenes, which are not activated through the presence of —I—M-substituents, undergo substitution smoothly under more forcing conditions with copper salts in pyridine or quinoline. Hence 3-cyanothiophene and 5-methyl-2-cyanothiophene have been obtained from the corresponding bromo compounds. 2-Bromothiophene reacts readily with aliphatic cuprous mercaptides in quinoline at 200°C to give thioethers in high yields. The use of the copper-catalyzed Williamson synthesis of alkoxythiophenes from iodo- or bromo-thiophenes and alcoholate has been mentioned before. The reaction of 2-bromothiophene with acetanilide in nitrobenzene in... 

The reaction of the isomeric 3-iodo-l-methylpyrazole-4-carboxylic acid with copper phenyl- and p-amylacetylide also leads to closure of the pyranopyrazole... 

To verify the generality of the cyclization of iodopyrazolecarboxylic acids, copper p-phenylbenzoylacetylide was used in the reaction with 3-iodo-l-methylpyra-zole-4-carboxylic acid. The assumed intermediate, alkynylpyrazolylcarboxylic acid, has a distribution of the electron density which is the most favorable for closure of the five-membered cyclic ether. However, the reaction leads only to the 5-lactone (Scheme 120). 

Thus, the cross-coupling of different iodo-A -methylpyrazolecarboxylic acids with copper acetylides leads to closure of the six-membered ring. 

Whereas the condensation of o-iodonitrobenzene with copper acetylides is accompanied by cyclization into isatogens, neither 4-iodo-3-nitro- nor 5-iodo-4-nitro-l,3-dimethylpyrazole gives cyclized products in conditions of acetylide synthesis. Moreover, nitropyrazolylphenylacetylene, as compared with o-nitrotolane, does not undergo thermal, catalytic, or photochemical isomerization to give the fused five-membered rings. 

TABLE XXV. Pyranopyrazoles Prepared by Cyclocondensation of vic-Iodo-pyrazolecarboxylic Acid with Copper(I) Acetylides [86TH1 78IZV1175 81IZV902 81IZV1342]. 

Treatment of 4-arylamino-8-iodoquinoline 268 with propargyl alcohol in presence of iodo(phenyl)bis(triphenylphosphine) palladium and copper (I)iodide afforded 269 which upon catalytic reduction using Linder s catalyst gave 4//-pyrrolo[3,2,l-(/]quinoline 270 (97H2395) (Scheme 48). 

Photolytically generated carbene, as mentioned above, undergoes a variety of undiscriminated addition and insertion reactions and is therefore of limited synthetic utility. The discovery (3) of the generation of carbenes by the zinc-copper couple, however, makes carbene addition to double bonds synthetically useful. The iodo-methylzinc iodide complex is believed to function by electrophilic addition to the double bond in a three-center transition state giving essentially cis addition. Use of the... 

Unsymmetrical 3,4-dihalo-l,2,5-thiadiazoles 118 and 119 were prepared from 3-amino-4-chloro-l,2,5-thiadiazole 117 via a Sandmeyer-like reaction involving successively tert-butyl nitrite and either copper bromide or copper iodide in anhydrous acetonitrile (Scheme 17) <2003H(60)29>. The bromo and iodo thiadiazoles 118 and 119 undergo selective Stille and Suzuki C-C coupling chemistry (see Section 5.09.7.6). 

Monoiodination of a zirconacyclopentadiene with one equivalent of iodine followed by the addition of one equivalent of CuCl gives the dimer of the cyclobutadiene and the Diels—Alder product in the presence of methyl maleate. This indicates the formation of a l-iodo-l,3-dienyl copper compound and the subsequent elimination of Cul to give a cyclobutadiene equivalent. Direct reductive elimination of zirconacydopentadienes affording cyclobutadienes has not yet been observed. 

A number of enantiomerically pure chiral building-blocks, such as 292-294, have been prepared (270,271) by zinc-copper cleavage of 5-bromo-5-deoxy-2,3-0-isopropylidene-D-ribono-1,4-lactone, followed by reduction. Similarly, from the 5-iodo lactone analogue the enoic acid 295 was obtained by reaction with zinc/silver-graphite (272). 

Treatment of 3,7,7-trimethylbicyclo[4.1.0]heptane (A3-carene) with iodine and copper acetate in methanol gave 3-iodo-4-methoxy-4,7,7-trimethylbicyclo[4.1.0] heptane. A 50 g sample exploded violently after standing at ambient temperature in a closed container for 10 days. This and the corresponding iodoacetoxy... 

Baker and co-workers observed during the synthesis of the biphenyl 74 (Scheme 19) from the iodo compound 73 by the Ullmann reaction at 230°C with copper bronze in nitrobenzene that the dibenzofuran 75 (1%)... 

Vapor phase pyrolysis of 2-aminobiphenyl in chloroform at 350°C produces carbazole,as does heating at 500-800°C in a high-frequency glow discharge at 25-34 A small amount (11%) of carbazole 280 was formed during the reaction of 281 with copper-potassium carbonate and 1-iodo-naphthalene in nitrobenzene. ... 

Electrophiles also react at C-5 of 1,3-dioxin-4-ones. Two ways of activation have been reported (1) magnesiation of 5-iodo-l,3-dioxin-4-ones afforded the Grignard reagents which can be cross-coupled with allyl halides in the presence of copper cyanide <2001TL6847> or with iodoalkenes under Pd(0) catalysis <2002T4787> and (2) Sc(OTf)3-catalyzed reaction of a side-chain-hydroxylated l,3-dioxin-4-one with aldehydes provided the bicyclic dioxinone in 60-85% yield (Scheme 27) <20050L1113>. 

Symmetrical biaryls are important intermediates for synthesising agrochemicals, pharmaceuticals and natural products (1). One of the simplest protocols to make them is the Ullmann reaction (2), the thermal homocoupling of aryl chlorides in the presence of copper iodide. This reaction, though over a century old, it still used today. It has two main disadvantages, however First, it uses stoichiometric amounts of copper and generates stoichiometric amounts of CuL waste (Figure 1, left). Second, it only works with aryl iodides. This is a problem because chemicals react by their molarity, but are quantified by their mass. One tonne of iodobenzene, for example, contains 620 kg of iodo and only 380 kg of benzene . 

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