Radicals, abstraction acyl from aldehydes with

The important role of reaction enthalpy in the free radical abstraction reactions is well known and was discussed in Chapters 6 and 7. The BDE of the O—H bonds of alkyl hydroperoxides depends slightly on the structure of the alkyl radical D0 H = 365.5 kJ mol 1 for all primary and secondary hydroperoxides and P0—h = 358.6 kJ mol 1 for tertiary hydroperoxides (see Chapter 2). Therefore, the enthalpy of the reaction RjOO + RjH depends on the BDE of the attacked C—H bond of the hydrocarbon. But a different situation is encountered during oxidation and co-oxidation of aldehydes. As proved earlier, the BDE of peracids formed from acylperoxyl radicals is much higher than the BDE of the O—H bond of alkyl hydroperoxides and depends on the structure of the acyl substituent. Therefore, the BDEs of both the attacked C—H and O—H of the formed peracid are important factors that influence the chain propagation reaction. This is demonstrated in Table 8.9 where the calculated values of the enthalpy of the reaction RjCV + RjH for different RjHs including aldehydes and different peroxyl radicals are presented. One can see that the value A//( R02 + RH) is much lower in the reactions of the same compound with acylperoxyl radicals. 

The acyl radicals obtained by hydrogen abstraction from aldehydes easily attack protonated heteroaromatic bases. With secondary and tertiary acyl radicals decarbonylation competes with the aromatic acylation [Eq. (12)]. 

Protonated pyridines and derivatives readily undergo acylation at C-2 or C-4 (Table 28) (76MI20503). Acyl radicals are usually generated either by hydrogen abstraction from aldehydes (Scheme 210), or by oxidative decarboxylation of a-keto acids (Scheme 211). In the former case (Scheme 210) with acridine as the substrate, reduction can take place to give a dihydroacridine. 

Difluoramino radicals also abstract hydrogen from aliphatic aldehydes to produce difluoramine. In addition, the acyl radical thus generated couples with an NF2 radical to produce a new class of organic compounds, the N,N-difluoramides... 

Acyl radicals are prduced in photolysis of diacetyl, when hydrogen is abstracted from aldehyde, or when an oxvgen atom or an ozone molecule reacts with olefin. 

One of the standard methods for the preparation of aldehydes involves the reduction of acid halides. A variety of stoichiometric reducing systems are available for this transfomiation, which include NaAlH(OBu-r)3, LiAlHfOBu-O.i, NaBHfOMe). Catalytic hydrogenation with H2 and Pd on carbon is also a popular method. In contrast, methods based on the radical reduction of acyl halides are synthetically less important. Radical reduction methods involve generation and subsequent hydrogen abstraction as key steps, which is complicated by decarbonylation of the intermediate acyl radicals. The first example in Scheme 4-1 shows that this competitive reaction is temperature dependent, where an acyl radical is generated from an acyl phenyl selenide via the abstraction of a phenylseleno group by tributyltin radical [5]. 

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 3.17 (p. 315), the acyl radicals are somewhat stabilized. The C—H BDE for acetaldehyde, which is 88.3 kcal/mol, decreases slightly with additional substitution but increases for The chain... 

A possible reaction path for the NHPI-catalyzed hydroacylation of alkenes with aldehydes is shown in Scheme 6.20. The reaction may be initiated by a hydrogen atom abstraction from the aldehyde by the radical initiator (In ), giving an acyl radical (C) which then adds to an alkene to afford a (i-oxocarbon radical (D). The resulting radical (D), having a nucleophilic character, abstracts the hydrogen atom from NHPI leading to ketone and PINO. The abstraction of the hydrogen atom from aldehyde by the PINO forms the acyl radical C and NHPI. An alternative formation of PINO from NHPI and radical initiator (In ) may also be possible. 

The oxidation reactions of aldehydes with OH in the presence of NOx are very important from the point of forming peculiar compoimds with strong biological toxicity called peroxy acyl nitrates (PANs, RC(0)00N02). The initial reaction of OH and aldehydes are H-atom abstraction forming the aldehyde group to form acyl radicals as seen in Chap. 5, Sect. 5.2.11. For example, in the case of acetaldehyde, the reaction mechanism is. 

Moreover, Bols et al. developed another methodology for the synthesis of carbamoyl azides from aldehydes by treatment with iodine azide at reflux in acetonitrile [41]. The carbamoyl azides are obtained in 70-97 % yield from the aliphatic and aromatic aldehydes (Scheme 5.4). When the reaction of phenyl-propanal with IN3 at 25 °C was performed in the presence of the radical trap, no acyl azide was observed, which was taken as support for a radical reaction mechanism. The mechanism shown in Scheme 5.6 is proposed for the reaction. Iodine radicals are formed by homolysis of the weak iodine-azide bond, abstracting the aldehyde hydrogen atom. The resulting carbon-centered radical reacts with iodine azide to produce an acyl azide. The following Cuitius rearrangement provides carbamoyl azides. 

In 2003, Bols and co-workers described that the reagent IN3 can easily transform the aldehydes into the acyl azides under mild conditions (Scheme 6.22a) [76]. Furthermore, they demonstrated that the synthesis of carbamoyl azides could be realized at reflux by combining the aldehyde C-H bond azidation and flie Cuilius rearrangement in a one-pot protocol (Scheme 6.22b). A possible radical mechanism were proposed for this transformation (Scheme 6.22c). The weak I-N3 bond homolysis can initiate the chain reaction. The generated iodine radical abstracts an aldehyde hydrogen atom from the substrates to produce the acyl radical A. The acyl radical A reacts with IN3 to afford the acyl azides and iodine radical, thereby sustaining the radical chain. 

Mechanisms of aldehyde oxidation are not firmly established, but there seem to be at least two main types—a free-radical mechanism and an ionic one. In the free-radical process, the aldehydic hydrogen is abstracted to leave an acyl radical, which obtains OH from the oxidizing agent. In the ionic process, the first step is addition of a species OZ to the carbonyl bond to give 16 in alkaline solution and 17 in acid or neutral solution. The aldehydic hydrogen of 16 or 17 is then lost as a proton to a base, while Z leaves with its electron pair. 

The acyl radical formed from acrolein, maintaining its coordination with a catalyst, may react preferably with oxygen, rather than decompose to produce carbon monoxide, though it is generally believed that a free acyl radical is formed after the abstraction of aldehyde hydrogen by a metal. In such a case, the catalyst metal is considered as behaving as a mononuclear, not a binuclear complex. The molecular weight of the catalyst recovered from the oxidation solution was measured (Table V). 

A new process for the homolytic acylation of protonated heteroaromatic bases has been developed by Minisci et al. An A-oxyl radical generated from iV-hydroxyphthalimide by oxygen and Co(ll) abstracts a hydrogen atom from an aldehyde. The resulting nucleophilic acyl radical adds to the heterocycle which is then rearomatized via a chain process. Under these conditions, quinoline and benzaldehyde afford three products (Equation 108) <2003JHC325>. A similar reaction with 4-cyanopyridine gives 2-benzoyl-4-cyanopyridine in 96% yield. 

In contrast to eq. 2.29, eq. 2.30 shows the oxidative conversion of aldehydes (62) to amides (63) via acyl bromides with NBS/AIBN/R2NH under refluxing conditions in CC14 [74]. The reaction comprises of the abstraction of the formyl hydrogen atom by the succinimidyl radical, bromine atom abstraction from NBS by the acyl radical, and lastly,... 

Sunlight irradiation (solar photochemical synthesis) of 1,4-naphthoquinone (27) in the presence of aldehyde (28) in a mixture of -butanol and acetone gives a good yield of the corresponding acyl hydroquinone (29) through the abstraction of the formyl hydrogen atom of aldehyde by the excited triplet biradical derived from 1,4-naphthoquinone, followed by the reaction of the acyl radical with 1,4-naphthoquinone (eq. 12.7). Here,... 

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