Bis bromine

Mono- or bis-bromine-lithium exchange on dibromopyrrole 77 affords stannylpyrroles 78 or 79, respectively, and N-BOC-2-trimethylstannylpyrrole is obtained in 75% yield from N-BOC pyrrole by lithiation with LTMP and quenching with Me3SnCl [15]. 

Similarly, the 2-cyano-6-oxazolopiperidine 75 (Scheme 16) can be used to provide a variety of substituted piperidines <99TL3731, 99H(51)2065>. Conversion to the enamide 76 provides a means to introduce C-3 alkyl groups by Michael reaction <99TL3699>. Electrochemical bis-bromination and dehydrohalogenation affords the vinyl bromide 77, which can imdergo substitution at the 4-position by the addition of nucleophiles as simple as water <99T8931>. 

Benzylic bromination of atropisomers has proven important in the preparation of a variety of dinapththazepine catalysts, like Maruoka s chiral, quaternary ammonium salt used for PTC. Amine 69 is considered a key building block for the preparation of this type of chiral catalyst. Bis-bromination of 67 provided 68 in 54% yield using NBS and catalytic AIBN in cyclohexane. Notably, the pure, bis-bromide 68 precipitates out of solution. Again, the benzyl bromide system was utilized as a leaving group. 

Oxidative cleavage of the complex 549 with CuCri affords 2,3-bis(chloro-methyl)-1,3-butadiene (550) and regenerates PdCri. Thus the preparation of this interesting dimerization product 550 can be carried out with a catalytic amount of PdCl2 and two equivalents of CuCb in MeCN[495], Similarly, treatment of allene with PdBr2 affords the dimeric complex 551. Treatment of this complex with 2 equiv, of bromine yields the dibromide 552. The tetra-bromide 553 is obtained by the reaction of an excess of bromine[496]. Similarly,... 

Bis(bexacbIorocycIopentadieno)cycIooctane. The di-Diels-Alder adduct of hexachlorocyclopentadiene [77 7 ] and cyclooctadiene (44) is a flame retardant having unusually good thermal stabiUty for a chlotinated aUphatic. In fact, this compound is comparable ia thermal stabiUty to brominated aromatics ia some appHcations. Bis(hexachlorocyclopentadieno)cyclooctane is usedia several polymers, especially polyamides (45) and polyolefins (46) for wire and cable appHcations. Its principal drawback is the relatively high use levels required compared to some brominated flame retardants. 

TetrabromobisphenolA. TBBPA is the largest volume reactive flame retardant. Its primary use is in epoxy resins (see Epoxyresins) where it is reacted with the bis-glycidyl ether of bisphenol A to produce an epoxy resin having 20—25% bromine. This brominated resin is typically sold as a 80% solution in a solvent. TBBPA is also used in the production of epoxy oligomers which are used as additive flame retardants. 

Copolymers. The copolymer of tetrabromoBPA and BPA was one of the first commercially successhil copolymers. Low levels of the brominated comonomer lead to increased flame resistance (V-0 rating by UL 94) while having htde effect on other properties. The polycarbonate of bis(4-hydtoxyphenyl)-l,l-dichlotoethylene, prepared from chloral and phenol, followed by dehydrohalogenation, was investigated as another flame-resistant polymer which retained good impact properties. 

By-products include propylene dibromide, bis-(bromopropyl) ether, propylene glycol, and propionic acid. Bromide losses are to the brominated organics and bromate formation. Current efficiency is a function of ceU design and losses to bromate. Energy consumption decreases with an increase in electrolyte concentration and a decrease in current density. Space—time yield increases with current density. See Table 5 for performance data (see... 

Bismuth Tribromide. Bismuth(III) bromide is a hygroscopic, golden-yeUow, crystalline soHd made up of pyramidal molecules. X-ray analysis has shown that the three bromines are 0.263 0.002 nm from the bismuth and the Br—Bi—Br angles are 100 4°. More recent nqr experiments indicate that the bromines are not equivalent (20). The soHd has a density of 5.72 g/mL and that of the Hquid is 4.572 g/mL at 271.5°C. 

Tetracyanoquinodimethane [1518-16-7] (5), 2,2 -(2,5-cyclohexadiene-l,4-diyhdene)bispropanedinitrile (TCNQ), is prepared by condensation of 1,4-cyclohexanedione with malononittile to give l,4-bis(dicyanomethylene)cyclohexane [1518-15-6] which is oxidized with bromine (31). 

The reaction of a dibromochalcone with hydroxylamine hydrochloride in pyridine gave three products with the expected 2-isoxazoline product as the predominate compound. A ring bromination product and an isoxazole were also isolated (70UC796). The reaction of hydroxylamine with /S-thiosulfates of propiophenone at reflux produced 3-phenyl-2-isoxazo-line (455). At room temperature a bis-Michael product (456) was produced. The reaction with N -phenylhydroxylamine yielded a mono-Michael type product (457) (74CPB1990). 

Quinoline, 2,4-bis(dimethylamino)-synthesis, 2, 419, 469 Quinoline, 3-bromo-bromination, 2, 319 oxidation, 2, 325 Skraup synthesis, 2, 467 Quinoline, 5-bromo-bromination, 2, 319 nucleophilic substitution, 2, 324 Quinoline, 6-bromo-nucleophilic substitution, 2, 324 Quinoline, 8-bromo-bromination, 2, 319 N-oxide... 

Use of the trapping agent is recommended as the most efficient method for running acyloin condensations for many reasons. Among them are (a) the work-up is very simple filter and distil (b) the bis-(silyloxy)olefin is usually easier to store than the free acyloin and is readily purified by redistillation (c) unwanted base-catalyzed side reactions during reduction are completely avoided and (d) the bis-(silyloxy)olefin can be easily converted directly into the diketone by treatment with 1 mole of bromine in carbon tetrachloride.Other reactions are described in Riihlmann s review and in Organic Reactions ... 

Bromine (Bi o) -6.6 59 5.5 0.1 Active Dark red liquid Dark red to reddish-brown... 

Biphenyl ether bis (2-Chloromethyl) ether bis (Dimethylaminoethyl) ether Bromine... 

The six-position may be functionalized by electrophilic aromatic substitution. Either bromination (Br2/CH2Cl2/-5°) acetylation (acetyl chloride, aluminum chloride, nitrobenzene) " or chloromethylation (chloromethyl methyl ether, stannic chloride, -60°) " affords the 6,6 -disubstituted product. It should also be noted that treatment of the acetyl derivative with KOBr in THF affords the carboxylic acid in 84% yield. The brominated crown may then be metallated (n-BuLi) and treated with an electrophile to form a chain-extender. To this end, Cram has utilized both ethylene oxide " and dichlorodimethyl-silane in the conversion of bis-binaphthyl crowns into polymer-bound resolving agents. The acetylation/oxidation sequence is illustrated in Eq. (3.54). 

The reaction of chlorine and bromine with cycloalkenes illustrates an important stereochemical feature of halogen addition. Anti addition is observed the two bromine atoms of Bi 2 or the two chlorines of CI2 add to opposite faces of the double bond. 

Neither bromine nor ethylene is a polar molecule, but both are polarizable, and an induced-dipole/induced-dipole force causes them to be mutually attracted to each other. This induced-dipole/induced-dipole attraction sets the stage for Br2 to act as an electrophile. Electrons flow from the tt system of ethylene to Bi, causing the weak bromine-bromine bond to break. By analogy to the customary mechanisms for electrophilic addition, we might represent this as the formation of a car bocation in a birnolecular- elementary step. 

Fluorination of an enamine, enol ether, or enol acetate with CF3OF gave 60-70% yields of fluoroketone (708). Bromination of an endiamine gave the bis-imonium salt (647). 

Bromination of the methyl group of (249) with A -bromosuccinimide, followed by reaction with excess secondary amine gave (250) which shows combined analgesic and antitussive properties. The Reformatsky reaction has also been used for the preparation of 2-amino-ethyl 3,3-diaryl-3-hydroxypropanates (251) as well as their dehydration products. The propene amides (252) have also been prepared for pharmacological evaluation. In l-methyl-3-bis (2-thienyl)-... 

Bis(bromomethyl)-5//-dibenz[/), / ]azepines, e.g. 12, prepared by free-radical bromination of the 10,11-dimethyl compound with yV-bromosuccinimide, on treatment with a primary alkyl-amine followed by alkaline hydrolysis, yield l,2,3,8-tetrahydrodibenzo[. /]pyrrolo[3,4-<7]-azepines, e.g. 13, which possess useful pharmacological properties.91,163... 

Bis(trimethylsilyl)propyne, 141 Bis(trimethylsilyl)terminai alkynols, 97 Borane-dimethyl sulphide. 84 Bromination-dcsilicobromination, 17-18... 

Braverman and Reisman111 have found that addition of a carbon tetrachloride solution of bromine to bis-y,y-dimethylallenyl sulfone 20 at room temperature unexpectedly resulted in spontaneous and quantitative fragmentation of the sulfone, with formation of the cyclic a, /3-unsaturated sulfmate (y-sultine) 43a and the tribromo products 44 and 45 (equation 38). Analogously, treatment of the same sulfone with trifluoroacetic acid gives rise to y-sultine 43b. It is interesting to note that from a synthetic point of view it is not even necessary to prepare the diallenyl sulfone 20, since one can use its sulfinate precursor (equation 24) to obtain exactly the same results, under the same conditions. The authors suggested that the fragmentation-cyclization of sulfone 20 may take place by the mechanism depicted in equation 39. 

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