Radical formylation

The reducing ability of one-electron reducing reagents, such as zinc, can be used in the radical formylation of alkyl iodides, where one-electron reduction and proton quenching constitute the final step in the production of aldehydes [19]. Unfortunately, this zinc method involves competing reactions and a narrow scope in terms of substrates. 

However, more rapid events, such as 5-exo cyclization and cyclopropylcarbinyl radical ring opening, can lead to radical formylation (Scheme 4-7). Thus, 1,6-dienes, when exposed to tin hydride/CO conditions, give fair yields of slannylfor-mylation products via cyclization (Scheme 4-7) [20J. On the other hand, treatment of vinylcyclopropanes with CO under similar reaction conditions leads to stannylformylation products via a cyclopropylcarbinyl radical opening to a homoallylic radical (Scheme 4-7) [21]. 

Radical Formylation of RX with a Sulfonyl Oxime Ether... 

It is noteworthy that this Cl reagent can be applied to a wide range of organic radicals involving rather stable radicals such as a-keto radical, a-alkoxyalkyl radical, and the benzyl radical for which the aforementioned radical formylation system with CO cannot be applied. The high reactivity of phenyl sulfonyl oxime ether is supported by kinetic studies [29]. The approximate rate constants for the addition of a primary alkyl radical to this phenyloxime ether was determined to be k=9.6xl0 M s at 25 °C, which is 1.8 times faster than the addition to aery-... 

A variety of carbonyl compounds can be prepared, using tin hydride as a radical mediator. Table 1 illustrates examples of radical formylation of several organic halides. The reaction can be applied to aromatic formylation [18] but not to stable radicals such as allyl, benzyl, alkoxymethyl, a-cyanoalkyl, and a-acylalkyl radicals. 

Recently, Miranda and coworkers reported that tin hydride-mediated radical carbonylation can be applied to include the synthesis of ketones fused with heterocyclic rings, such as pyrroles and indoles. In the example given in run 10, an acyl radical attack at aromatic carbon and in situ oxidation leads to an indole-fused cyclopentanone in good yield [39]. On the other hand, an example shown in run 11 makes use of a methanesulfonyl group as a leaving radical [40]. When a related substrate which does not contain a sulfonyl substituent was used, a simple radical formylation took place. 

Reactions with Radicals. Isoquinoline does react with radicals to give addition to the 1-position with subsequent loss of hydrogen. The Minisci reaction is a well-known example of this transformation. It is an effective reaction for the addition of hydroxymethyl, alkyl, and acyl radicals. Formyl and carbamoyl groups have also be added using this method. Acidic conditions help to promote the reaction. Alkylation is effective when carried out with alkyl iodides or alkyl xanthates. Hydroxymethyla-tion can also be carried out. Photochemical-induced free radical reactions have also been reported. Alkylation is possible using ethanol or propanoic acid but low yields are often obtained. Addition of a phenyl group can be achieved in 81% yield. ... 

Acyl Halides. Acyl halides, in which the hydroxyl portion of a carboxyl group is replaced by a halogen, are named by placing the name of the corresponding halide after that of the acyl radical. When another group is present that has priority for citation as principal group or when the acyl halide is attached to a side chain, the prefix haloformyl- is used as, for example, in fiuoro-formyl-. 

Pyrrole, 2-methyoxycarbonyl-1 -methyl-formylation, 4, 45 Pyrrole, nitro-rearrangement, 4, 297 Pyrrole, 2-nitro-nitration, 4, 211 photolysis, 4, 203 radical methylation, 4, 260 synthesis, 4, 210, 362 Pyrrole, 3-nitro- N NMR, 4, 13 nitration, 4, 211 synthesis, 4, 49, 210, 362 Pyrrole, nitroso-rearrangement, 4, 297 Pyrrole, 2-nitroso-reactions... 

Other functional groups provide sufficient stabilization of radicals to permit successful chain additions to alkenes. Acyl radicals are formed by abstraction of the formyl hydrogen from aldehydes. As indicated in Table 12.7, the resulting acyl radicals are... 

Complete dissociation of the primary product (160) would result in the loss of the formyl fragment and in the stabilization of the remaining oxydiene radical by hydrogen abstraction from any suitable donor. As a competitive primary photoprocess bridging between the C-5 jS-carbon and the... 

Favorskii rearrangement, 159, 176 Formation of hetero-radicals, 238 2-Formyl-A-nor-5a-androstan-l 7 -oI, 415 2-Formyl-A-nor-5 a-androst-1 -en-17 S-ol, 416 6/3-Formyl-B-nor-5 -cholestane-3, 5 -dioI 3-acetate, 432... 

We return briefly to the formyl radical of Eq. (8-5), a by-product of the initiation reaction. The following sequence is believed to constitute a chain process that couples with the other sequence [Eqs. (8-5)—(8-8)] ... 

Formaldehyde-to-phenol ratios, 404 V-Formyl amines, 158 Fourier transform infrared (FTIR) spectrometry, 116, 300, 387, 407-408 Fradet, Alain, 17 Free-radical copolymerization, 59 Friedel-Crafts acrylation polymerization, 332-334... 

CHsSNa in an aprotic solvent or by BusSnH. Both reactions have free-radical mechanisms.Tertiary nitro compounds can be reduced to RH by NaHTe. The compound Bu3SnH also reduces isocyanides (RNC, prepared from RNH2 by formylation followed by 17-33) to a reaction that can also be... 

Until now, applications of semiempirical all-valence-electron methods have been rare, although the experimental data for a series of alkyl radicals are available (108,109). In Figure 9, we present the theoretical values of ionization potentials calculated (68) for formyl radical by the CNDO version of Del Bene and Jaffe (110), which is superior to the standard CNDO/2 method in estimation of ionization potentials of closed-shell systems (111). The first ionization potential is seen, in Figure 9, to agree fairly well with the experimental value. Similarly, good results were also obtained (113) with some other radicals (Table VII). 

Figure 9. Determination of the first electron affinity, and the first and higher ionization potentials of formyl radical from the SCF orbital energies and electronic repulsion integrals, and K,j (cf. eqs. (90), (92), and (93)). The experimental value (112), 9.88 eV, for the first ionization potential corresponds to the theoretical value I . All entries are given in eV. With A and I a lower index stands for MO the upper one indicates the state multiplicity after ionization.

A key step proposed in the radical chain mechanism for the formation of the formyl complex is the coordination of CO to the Rh(OEP)- monomer, to give an intermediate carbonyl complex, Rh(OEP)(CO)- which then abstracts hydride from Rh(OEP)H to give the formyl product.This mechanism was proposed without direct evidence for the CO complex, and since then, again from the research group of Wayland, various Rh(fl) porphyrin CO complexes, Rh(Por)(CO), have been observed spectroscopically along with further reaction products which include bridging carbonyl and diketonate complexes. 

When formic acid was codeposited at 14 K with a beam of excited argon atoms, formyl radical, HOCO, was produced (12) in sufficient yield for the IR detection of most of its vibrational fundamentals (Jacox, 1988). Detailed analysis of the matrix spectra of isotopically (D, C and 0) labelled formyl radical showed absorptions at 3603, 1844 and 1065cm , which correspond to the stretching vibrations of O—H, C=0 and C—O bonds. 

The reaction of volatile chlorinated hydrocarbons with hydroxyl radicals is temperature dependent and thus varies with the seasons, although such variation in the atmospheric concentration of trichloroethylene may be minimal because of its brief residence time (EPA 1985c). The degradation products of this reaction include phosgene, dichloroacetyl chloride, and formyl chloride (Atkinson 1985 Gay et al. 1976 Kirchner et al. 1990). Reaction of trichloroethylene with ozone in the atmosphere is too slow to be an effective agent in trichloroethylene removal (Atkinson and Carter 1984). 

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