Hydrogen bromide ethers

A mechanism for the cleavage of diethyl ether by hydrogen bromide is outlined m Figure 16 4 The key step is an 8 2 like attack on a dialkyloxonmm ion by bromide (step 2)... 

FIGURE 16 4 The mechanism for the cleavage of ethers by hydrogen halides using the reac tion of diethyl ether with hydrogen bromide as an example... 

Cleavage of alkyl aryl ethers by hydrogen halides always proceeds so that the alkyl-oxygen bond is broken and yields an alkyl halide and a phenol as the final prod nets Either hydrogen bromide or hydrogen iodide is normally used... 

Isopropyl phenyl ether + excess hydrogen bromide + heat... 

Hydrogen bromide adds to acetylene to form vinyl bromide or ethyHdene bromide, depending on stoichiometry. The acid cleaves acycHc and cycHc ethers. It adds to the cyclopropane group by ring-opening. Additions to quinones afford bromohydroquinones. Hydrobromic acid and aldehydes can be used to introduce bromoalkyl groups into various molecules. For example, reaction with formaldehyde and an alcohol produces a bromomethyl ether. Bromomethylation of aromatic nuclei can be carried out with formaldehyde and hydrobromic acid (6). 

Ethers. In the presence of anhydrous agents such as ferric chloride (88), hydrogen bromide, and acid chlorides, ethers react to form esters (see Ethers). Esters can also be prepared from ethers by an oxidative process (89). With mixed sulfonic—carboxyhc anhydrides, ethers are converted to a mixture of the corresponding carboxylate and sulfonate esters (90) ... 

The high reactivity of pyrroles to electrophiles is similar to that of arylamines and is a reflection of the mesomeric release of electrons from nitrogen to ring carbons. Reactions with electrophilic reagents may result in addition rather than substitution. Thus furan reacts with acetyl nitrate to give a 2,5-adduct (33) and in a similar fashion an adduct (34) is obtained from the reaction of ethyl vinyl ether with hydrogen bromide. 

Violent reaetions have oeeuiTed between ozone and many ehemieals, a small seleetion being aeetylene, alkenes, dialkyl zines, benzene/mbber solution, bromine, earbon monoxide and etliylene, diethyl ether, hydrogen bromide, and nitrogen oxide. 

Treatment of dibromocarbene adduct (43) (Rji, = O) with aqueous methanol containing silver nitrate or perchlorate gives A-homo-estra-1 (10), 2,4a-triene-4,17-dione (45) in 21 % overall yield from the enol ether (42). The exact pathway is not known, but the first step may be formation of a bromo-homo-dienone facilitated by the methoxyl group, which then undergoes further loss of hydrogen bromide involving shift of a double bond by enolization. ... 

Dehydrochlorination of bis(tnfluoromethylthio)acetyl chloride with calcium oxide gives bis(trifluoromethylthio)ketene [5] (equation 6) Elimination of hydrogen chloride or hydrogen bromide by means of tetrabutylammonium or potassium fluoride from vinylic chlorides or bromides leads to acetylenes or allenes [6 (equation 7) Addition of dicyclohexyl-18-crown-6 ether raises the yields of potassium fluoride-promoted elimination of hydrogen bromide from (Z)-P-bromo-p-ni-trostyrene in acetonitrile from 0 to 53-71 % In dimethyl formamide, yields increase from 28-35% to 58-68%... 

Esters of diphenylacetic acids with derivatives of ethanol-amine show mainly the antispasmodic component of the atropine complex of biologic activities. As such they find use in treatment of the resolution of various spastic conditions such as, for example, gastrointestinal spasms. The prototype in this series, adiphenine (47), is obtained by treatment of diphenyl acetyl chloride with diethylaminoethanol. A somewhat more complex basic side chain is accessible by an interesting rearrangement. Reductive amination of furfural (42) results in reduction of the heterocyclic ring as well and formation of the aminomethyltetrahydro-furan (43). Treatment of this ether with hydrogen bromide in acetic acid leads to the hydroxypiperidine (45), possibly by the intermediacy of a carbonium ion such as 44. Acylation of the alcohol with diphenylacetyl chloride gives piperidolate (46). ... 

To a solution of 30.7 g (0.203 mol) of 1-phenoxy-2-aminopropane in 150 ml of ethanol there was added 31.9 g (0.100 mol) of 1-(4 -benzyloxyphenyl)-2-bromopropanone-1. The mixture was heated to boiling temperature and the solution was then refluxed in a reflux condenser for 3 hours. Most of the ethanol was then distilled off in vacuo. Then to the residue there was added about 150 ml of diethyl ether. The hydrogen bromide salt of 1-phenoxy-2-aminopropane was filtered off and washed with diethyl ether. 

The solvents were then evaporated, y.ielding 4-[(2-methvl-1,2-dicarbobenzoxyhvdrazino)-methyl]-benzoic acid isopropylamide as a yellow oil, which crystallized upon triturating with ether MP 90°-92 C. This product was then covered with 70 ml of a 33% solution of hydrogen bromide in glacial acetic acid, and then permitted to stand for 2 hours with occas-... 

The alicyclic analogs 4 with hydrogen bromide in diethyl ether at room temperature behave similarly to yield the 4,5-fused 7-bromo-3/7-azepin-2-amines 5 as their hydrobromide salts. Yields are high except for the cyclooctane derivative (n = 4). Once again, the free bases are liberated by treatment with sodium hydrogen carbonate. 

Cyclohexene 6 undergoes cyclization with hydrogen bromide in diethyl ether at 0 C to give l-bromo-6,7,8,9-tetrahydro-477-2-benzazepin-3-amine hydrobromide (7), rather than the alternative isomer, 3-broino-7,8,9,9a-tetrahydro-6//-2-bcnzazcpin-l-amine (8). 

Benzene- 1,2-diacetonitriles e.g. 19, in the presence of hydrogen bromide in acetic acid, or in diethyl ether, cyclize to 4-bromo-l //-3-benzazepin-2-amines, e.g. 20a.41,42 l//-Naphtho[2,3-t/]azepines, e.g. 22a, are prepared in a similar manner from naphthalene-2,3-diacetonitriles, e.g. 21.41 Replacement of hydrogen bromide by hydrogen iodide yields the corresponding 4-iodo derivatives, e.g. 20b and 22b. 

Bradfield et al.21g first studied the kinetics of molecular bromination using aromatic ethers in 50% aqueous acetic acid at 18 °C. They showed that the kinetics are complicated by the hydrogen bromide produced in the reaction which reacts with free bromine to give the tribromide in BrJ, a very unreactive electrophile. To avoid this complication, reactions were carried out in the presence of 5-10 molar excess of hydrogen bromide, and under these conditions second-order rate coefficients (believed to be I02k2 by comparison with later data) were obtained as follows after making allowance for the equilibrium Br2 + Br7 Bn, for which K = 50 at 18 °C 4-chloroanisole (1.12), 4-bromoanisole (1.20), 4-... 

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