Benzoyl chloride, reduction

A) Benzoyl Derivative. Since acetylation and benzoylation do not always proceed smoothly with nitrophenols, it is best to reduce them to the aminophenol as in (3) above. Add an excess of 20% aqueous sodium hydroxide to the reaction mixture after reduction, cool and then add a small excess of benzoyl chloride, and shake in the usual way. The dibenzoyl derivative wiU separate. Filter, wash with water and recrystalUse. (M.ps., p. 551.)... 

Trimethylene dibromide (Section 111,35) is easily prepared from commercial trimethj lene glycol, whilst hexamethylene dibromide (1 O dibromohexane) is obtained by the red P - Br reaction upon the glycol 1 6-hexanediol is prepared by the reduction of diethyl adipate (sodium and alcohol lithium aluminium hydride or copper-chromium oxide and hydrogen under pressure). Penta-methylene dibromide (1 5-dibromopentane) is readily produced by the red P-Brj method from the commercially available 1 5 pentanediol or tetra-hydropyran (Section 111,37). Pentamethylene dibromide is also formed by the action of phosphorus pentabromide upon benzoyl piperidine (I) (from benzoyl chloride and piperidine) ... 

The reaction of benzoyl chloride with (Me3Si)2 affords benzoyltrimethylsi-lane (878)[626,749,750]. Hexamethyldigermane behaves similarly. The siloxy-cyclopropane 879 forms the Pd homoenolate of a ketone and reacts with an acyl halide to form,880. The 1,4-diketone 881 is obtained by reductive elimination of 880 without undergoing elimination of /7-hydrogen[751]. 

Isoquinoline also forms Reissert compounds when treated with benzoyl chloride and alkyl cyanide (28), especially under phase-transfer conditions (29). The W-phenylsulfonyl Reissert has been converted to 1-cyanoisoquinoline with sodium borohydride under mild conditions (154). When the AJ-benzoyl-l-alkyl derivative is used, reductive fission occurs and the 1-alkyLisoquinoline is obtained. 

The only industrially important processes for the manufacturing of synthetic benzaldehyde involve the hydrolysis of benzal chloride [98-87-3] and the air oxidation of toluene. The hydrolysis of benzal chloride, which is produced by the side-chain chlorination of toluene, is the older of the two processes. It is no longer utilized ia the United States. Other processes, including the oxidation of benzyl alcohol, the reduction of benzoyl chloride, and the reaction of carbon monoxide and benzene, have been utilized ia the past, but they no longer have any iadustrial appHcation. 

An 80% yield of tetraphenylfuran is obtained by treatment of benzoyl chloride with active titanium generated by lithium aluminum hydride reduction of titanium trichloride (Scheme 84e) (8UOC2407). The reaction nroceeds via benzil and tetraphenylbut-2-ene-l,4-dione, both of which are minor products of the reaction. 

This method is an adaptation of that of Dengel. -Methoxy-phenylacetonitrile can also be prepared by the metathetical reaction of anisyl chloride with alkali cyanides in a variety of aqueous solvent mixtures by the nitration of phenylaceto-nitrile, followed by reduction, diazotization, hydrolysis, and methylation 1 by the reduction of ct-benzoxy- -methoxy-phenylacetonitrile (prepared from anisaldehyde, sodium cyanide, and benzoyl chloride) and by the reaction of acetic anhydride with the oxime of -methoxyphenylpyruvic acid. ... 

Incorporation of extensive branching in the side chain similarly does not decrease pharmacologic activity. Reductive alkylation of aminoalcohol, 42, with isobutyraldehyde affords the amine, 43. Acylation of the amine with benzoyl chloride probably goes initially to the amide (44). The acid catalysis used in the reaction leads to an N to 0 acyl migration to afford iso-bucaine (45). ... 

In an analogous sequence, reductive alkylation of aminoalcohol, 46, with cyclohexanone affords the secondary amine (47). Acylation with benzoyl chloride affords hexylcaine (48) in a reaction that may again involve acyl migration. 

The oxygen atom in these molecules can in many cases be dispensed with as well substitution of sulfur for nitrogen affords a molecule whose salient biologic properties are those of a sedative and tranquilizer. Friedel-Crafts acylation of the n-butyl ether of thiophenol with benzoyl chloride gives the corresponding benzophenone. Reduction of the ketone (15) followed by... 

Diastereomer 155 was most conveniently prepared by treatment of 70 (R = Bn) with BuLi followed by benzoyl chloride, to give carbonyl compound 154 and then subsequent stereoselective reduction with LiBI I4 (Scheme 13) < 1997TL7753>. Interestingly, the O-ttr-isomer 69 gives a rearranged product 156 after benzoylation (Scheme 14) <2002JA13154>. 

In the case of mono-ester substituted pyrroles (e.g., 68) wherein relatively unstable dianions likely to deprotonate ammonia might be produced, the authors instead utilized an excess of (MeOCH2CH2)2NH as a substitute for ammonia. It was felt that upon in situ formation of (MeOCH2CH2)2NLi, this base would be unable to protonate the dianion <00TL1331>. Remarkably, quenching the reduction reactions with benzoyl chloride affords P-keto esters (e.g., 69, R = COPh), a reaction that does not occur when conducted in liquid ammonia. 

A number of optically active 1,1 -binaphthyl compounds, 8168 and 9,169 have been prepared with a view to use them as asymmetric catalysts. Compounds 8 (X = Br and OTf)170,171 and 9 [R3 = Me(OTf)2]169 have been used to resolve diols in their reaction with benzoyl chloride. Tin hydrides based on structure 8 (X2 = MeH,172 Bu H,173 and Me3CCH2H171) have been designed for carrying out enantioselective reductions. 

A viable iron carbonyl-mediated reduction process converts acid chlorides and bromoalkanes into aldehydes [3, 6]. Yields are high, with the exception of nitro-benzoyl chloride, and the procedure is generally applicable for the synthesis of alkyl, aryl and a,(i-unsaturated aldehydes from the acid chlorides. The reduction proceeds via the initial formation of the acyl iron complex, followed by hydride transfer and extrusion of the aldehyde (cf. Chapter 8). 

Reduction of benzoyl chloride at mercury yields an acyl radical that dimerizes to form benzil. As quickly as it forms, benzd accepts an electron to form an anion radical that is acylated by a molecule of benzoyl... 

In addition to studying the behavior of benzoyl chloride. Cheek and Horine [72] have examined the reduction of benzoyl fluoride electrolysis of the latter compound affords benzyl benzoate, diphenyl-acetylene, stilbenol benzoate, and some polymers. Another feature of the reduction of benzoyl chloride is the possibility that both acyl radicals and acyl anions are involved as intermediates [71]. 

Linear sweep voltammetry of ben2x yl chloride in acetonitrile containing tetra-ethylammonium fluoroborate shows Ep == -1.4 V vs. see and for heptanoyl chloride Ep = -2,2 V vs. see [169] The one-electron reduction of acid chlorides at these potentials is a source of carbonyl radicals. Reduction of benzoyl chloride at the peak... 

The reduction of aroyl chlorides take a different course in the presence of Ni(ll) salts. Reaction is best effected in an undivided cell with a nickel anode and a nickel foam cathode with acetonitrile containir tetrabutylammonium fluoroborate as electrolyte. Symmetrical ketones are formed [173], Substimted benzoyl chlorides yield the benzophenone in 47-72% yields. Phenacetylchloride also gives the ketone in good yield but in general, alkanoyl chlorides do not react. 

While there is ample room for debate at the theoretical level, the importance of this straightforward route to compound 20 could hardly be missed. Attention could now be directed to the necessary functional group adjustments. Reduction of the ester (lithium triethoxyborohydride) followed by benzoylation (benzoyl chloride, DMAP) afforded an 80% yield of 22. Treatment of this compound with ruthenium dioxide in the presence of sodium metaperiodate, followed by diazomethane, provided ester 23 in 90% yield. 

---