Aryl methanol, formation

The oxidative aromatization of tetrahydro-5(l/f)-quinolinones and tetrahydropyrido [2,3-fif]pyrimidin-4(//)-one withpara-benzaldehydes as oxidants in NaOEt/EtOH results in the formation of the corresponding quinolone and aryl methanol because of the hydride transfer from tetrahydroquinoline to arylaldehydes during the oxidation process. The yield of the products basically depends on the substituents with -l-M effect attached to the para position of benzene rings connected to the 2- and 4-positions of the hydro-quinolinone moiety and substituents with -I effect attached to the aryl aldehydes. 

There is evidence from a detailed study of the photolyses of 2-alkyl-substituted aryl azides 40 in diethylamine that A3,7V-diethyl-1 //-azepin-2-amines are formed as oxygen-sensitive, meta-stablc intermediates that can give rise to a variety of byproducts, including 5-acyl- A%V-diethyl-pyridin-2-amines and 6-alkyl-7-(diethylamino)-2//-azepin-2-ones 11 however, formation of these oxidation products can be avoided by refluxing the photolysate mixture with methanol prior to exposure to oxygen, in which case practicable yields of the /V,/V-diethyl-3W-azepin-2-amines 41 result. 

Horner and Stohr (1952) found that in methanol the photolytic formation of the aryl methyl ether is rather a minor process, the main reaction being a hydro-de-di-azoniation. In a comparison between thermal and photolytic dediazoniation in water, Lewis et al. (1969 b) analyzed the percentages of chloro-de-diazoniations for three arenediazonium chlorides in aqueous solution in the presence of various concentrations of NaCl under both thermal and photolytic conditions. The authors came to the conclusion that these processes do not involve the same intermediates. 

The fact that only the vinyl-substituted l,2X5-oxaphosphetanes 22 but not the arylated phosphorus heterocycles 21 undergo photofragmentations is presumably due to the inability of the latter to absorb the light (X > 280 nm) supplied for carbene formation (7- 8) [e.g. 21, Ar = C6H5 e280 200 22b, d e2g0 9000 (in methanol)]I8,20). 

For example, McNab and coworkers have discovered that flash-vacuum pyrolysis (FVP) (1000 °C, 0.01 Torr) of pyrrole 10-114 led to the formation of pyrrolo[2,l-a]isoindol-5-one 10-117 in 79% (Scheme 10.29) [44]. The transformation is proposed to proceed via an initial 1,5-aryl shift to give intermediate 10-115, which then undergoes an elimination of methanol. Finally, electrocydization of the ketene 10-116 results in the formation of 10-117. 

Phenyl aryl cyclopropenones16 were cleaved by methanolic KOH to a mixture of cis aryl cinnamic acids (318/319 R = phenyl, R = aryl), whose rates of formation gave rise to a linear Hammett-type correlation with a values in the range of -0.268 to +0.373 and p = 0.75. This also indicates that cleavage yielding the more stable carbanion is preferred. Interestingly, ortho-substituted aryl phenyl cyclopropenones gave only a-phenyl-0-aryl acrylic acids (319 R = phenyl, R = aryl), which was explained in terms of steric interactions. 

The asymmetric formation of industrially useful diaryl methanols can be realized through either the addition of aryl nucleophiles to aromatic aldehydes or the reduction of diaryl ketones. The latter route is frequently the more desirable, as the starting materials are often inexpensive and readily available and nonselective background reactions are not as common. For good enantioselectivity, chemical catalysts of diaryl ketone reductions require large steric or electronic differentiation between the two aryl components of the substrate and, as a result, have substantially limited applicability. In contrast, recent work has shown commercially available ketoreductase enzymes to have excellent results with a much broader range of substrates in reactions that are very easy to operate (Figure 9.6). ... 

Prior to imide formation, the imide-aryl ether ketimine copolymers were converted to the imide-aryl ether ketone analogue by hydrolysis of the ketimine moiety with para-toluene sulfonic acid hydrate (PTS) according to a literature procedure [51,52,57-59]. The copolymers were dissolved in NMP and heated to 50 °C and subjected to excess PTS for 8 h. The reaction mixtures were isolated in excess water and then rinsed with methanol and dried in a vacuum oven to afford the amic ester-aryl ether ether ketone copolymer, 2e (Scheme 8.)... 

As mentioned above, iridium complexes are also active in the formation of amines via the hydrosilylation/protodesUylation of imines. In the presence of 2 equiv. of HSiEts, the cationic complex [lr bis(pyrazol-l-yl)methane (CO)2][BPh4] (C4) catalyzes the reduction of various imines, including N-alkyl and N-aryl imines and both aldimines and ketimmes. Excellent conversions directly to the amine products were achieved rapidly at room temperature in a methanol solution (Scheme 14.7) [53]. 

Let us now consider the formation of aryl iodides from aryl diazonium salts and potassium iodide in methanol (Singh and Kumar 1972a, 1972b). Electron-donor substituents decelerate the process as compared with benzene diazonium (the substituent is hydrogen), whereas electron acceptor substituents accelerate it. Oxygen inhibits the reaction, and photoirradiation speeds it up. As the authors pointed out, in the case of 4-nitrobenzene diazonium, the reaction leads not only to 4-iodonitrobenzene but also to nitrobenzene, elemental iodine, and formaldehyde. All of these facts support the following sequence of events ... 

Aromatic members of this series (XIV R = Aryl, R = H or Aryl) reacted with alkylamines in methanol under a variety of conditions to afford variable yields (20—90%) of biguanides (55, 577). In many examples, however, cyanoguanidine was again the main product, its formation being apparently favoured by the presence of water (55). 

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