Iodobenzene 3-chloro

The rates of the reactions fall into two pairs and follow a U-shaped sequence fluorobenzene nitrates most quickly, followed closely by iodobenzene chloro-, and bromobenzene nitrate at around half these rates. Chlorine and bromine suffer because both are quite electronegative and neither has good lone pair overlap in fluorine, overlap is good in iodine, electronegativity is much less. 

The iodine atom in iodobenzene (unlike that in the corresponding aliphatic compounds) is very resistant to the action of alkalis, potassium cyanide, silver nitrite, etc. This firm attachment of the iodine atom to the benzene ring is typical of aromatic halides generally, although in suitably substituted nitio-compounds, such as chloro-2,4-dinitrobenzene, the halogen atom does possess an increased reactivity (p. 262). 

Under conditions in which benzene and its homologues were nitrated at the zeroth-order rate, the reactions of the halogenobenzenes ([aromatic] = c. o-1 mol 1 ) obeyed no simple kinetic law. The reactions of fluorobenzene and iodobenzene initially followed the same rates as that of benzene but, as the concentration of the aromatic was depleted by the progress of the reaction, the rate deviated to a dependence on the first power of the concentration of aromatic. The same situation was observed with chloro- andjbromo-benzene, but these compounds could not maintain a zeroth-order dependence as easily as the other halogenobenzenes, and the first-order character of the reaction was more marked. 

Metalation. Benzene reacts with alkaH metal derivatives such as methyl or ethyUithium ia hydrocarbon solvents to produce phenyUithium [591 -51 -5], CgH Li, and methane or ethane. Chloro-, bromo-, or iodobenzene will react with magnesium metal ia ethereal solvents to produce phenyHnagnesium chloride [100-59-4], C H MgCl, bromide, oriodide (Grignard reagents) (32). 

Fig. 8. Product yields and polarization (100 MHz) in the thermal decomposition (126°C) of 4-chlorobenzoyl peroxide (0-1 m) in hexachloroacetone containing iodine and water. Curve A, 4-ohlorobenzoic acid ([HjO], ca. 0-03 M) Curve B, p-chloroiodobenzene ([H2O], CO. 0-03 m) Curve C 4-chIorobenzoic acid ([HaO], ca. 1-6 m) Curve D, p-chloro-iodobenzene ([H O], ca. 1-6 m) Curve E, maximum intensity of emission from p-chloro-iodobenzene (O, co. 0-03 m H2O , ca. 1-6 M H2O). Data of Blank and Fischer, 1971b.

Hydrodehalogenations of chloro-, bromo-, and iodobenzene were carried out individually as well as in competitive reactions. When the reactions were carried out separately, the reduction of chlorobenzene closely paralleled that of bromobenzene, whereas the reduction of iodobenzene was slower. When they were allowed to react competitively, the reduction was highly selective, and the reaction was delayed, but iodobenzene reacted first followed by bromobenzene and then chlorobenzene. 

Representative of recent applications of the reaction to the synthesis of heterocycles are the photodehydrochlorination of chlorobenzo[b]thiophen (347) to give the fused pyrimidone 348,287 the photoelimination of HI from iodobenzene derivatives 349 to give the benzazepines 350,288 and the synthesis of the medium ring aza-heterocycle 351 by irradiation of the chloro precursor 352.289 Included among the many other examples of... 

We continued our work with the reductive Heck and Domino-Heck reactions [1, 7J of new bicyclic compound (3) by treating it with different aryl- and hetaryl-iodides, as a result a series of new epibatidine analogues were synthesized, continuously separated and purificated by column chromatography on silica gel. Treatment of 3 with iodobenzene, 2-iodothiophene, 1-iodonapthalene and 2-chloro-5-iodopy-ridine under reductive Heck conditions gave new compounds 4a-d and 5b, 5d as exo-regioisomers after chromatographic separations. The reactions with iodobenzene and 1-iodonapthalene gave only 5-exo- products. The use of trimethylsily-lacetylene under Domino-Heck conditions provided alkynic bicyclic systems 6e andf. 

Similar decomposition is observed in p-bromoacetophenone, o-bromo-, p-bromo, and p,p -dibromobenzophenone, and p-iodobenzophenone44 but not in the fluoro- and chloro-substituted compounds. This order of reactivity follows the bond dissociation energies for aromatic halides which are about 90 kcal/mole for chlorobenzene, 70 kcal/mole for bromobenzene, and 60 kcal/ mole for iodobenzene. The lowest-lying triplet of p-bromoacetophenone is 71.2 kcal45 while that of the substituted benzophenones is slightly lower since benzophenone itself has a lower triplet energy than acetophenone. p,p Dibromobenzophenone was the least reactive of the compounds that photoeliminated halogen atoms. 

The 2- and 4-picolyl anions are phenylated or mesitylated on reaction with chlorobenzene, phenyltri-methylammonium ion and 2-bromomesitylene under stimulation by light or potassium metal. The mechanism of reaction with bromobenzene and iodobenzene is not certain, with die aryne mechanism almost certainly intruding, and with iodobenzene some diarylation of the picolinyl anion results. The reaction of the 2-picolyl anion with 2-bromomesitylene, where an aryne process is impossible, is shown in equation (44). Similar reactions take place between the 4-picolyl anion and 2- or 4-bromopyridine or 2-chloro-quinoline.134... 

Essentially the same substituents as listed above may be present in the alkene being substituted, with the possible exception of chloro, alkoxy and acetoxy groups on vinyl or allyl carbons. These groups, especially chloro, may be lost or partially lost with palladium when the final elimination step occurs. For example, vinyl acetate, iodobenzene and triethylamine with a palladium acetate-triphenylphosphine catalyst at 100 C form mainly (E)-stilbene, presumably via phenylation of styrene formed in the first arylation step (equation 21 ).6 ... 

The role of molecular dimensions is well demonstrated by complex formation with halogen-ated benzenes. 1 1 complexes may be prepared from chloro-, bromo-, and iodobenzenes but from chlorobenzene only witto-CD, from bromobenzene witb- andp-CDs, and from iodobenzene with P- andy-CDs. 

Common Name 2-Chloroiodobenzene Synonym 2-chloro-l-iodobenzene Chemical Name ... 

The corresponding chloro and bromo compounds as well as the 3-iodo and 4-iodophenyl compounds are photostable. A mechanism is proposed in which the primary excited S, state crosses into an ncr state in the iodobenzene manifold. This is followed by homolysis of the C—I bond. The aryl radical may undergo ring closure or abstract a hydrogen atom from the solvent. The primary ring-closed product is photo-oxidized under the reaction conditions. 

The first alkynyliodonium salt, (phenylethynyl)phenyliodonium chloride, synthesized in low yields from (dichloroiodo)benzene (3) and lithium phenylacetylide (equation 1), was reported in 196526. This chloride salt is unstable and readily decomposes to a 1 1 mixture of chloro(phenyl)acetylene and iodobenzene. It was not until the 1980s, however, that alkynyliodonium salts became generally available. This was made possible by the introduction of sulfonyloxy-/l3-iodanes as synthetic reagents46 and by the recognition that iodosylbenzene (4) can be activated either with boron trifluoride etherate or with triethy-loxonium tetrafluoroborate31. These reagents are now widely employed for the conversion of terminal alkynes and their 1-silyl and 1-stannyl derivatives to alkynyliodonium salts (equations 2 and 3). A more exhaustive survey of iodine(III) reagents that have been... 

Two novel variations on remote oxidation involve radical relay mechanisms. Chlorine radicals generated by photolysis of iodobenzene dichloride are carried by the iodine atom of a suitable iodo-aryl ester of 5a-cholestan-3a-ol to permit hydrogen abstractions from C-9 or C-14, depending upon the ester employed.237 The m-iodobenzoate (293) afforded the 9a-chloro- and thence the cholest-9(ll)-ene derivative (294), whereas the p-iodophenylacetate similarly gave a 14-ene. 

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