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Boron reactions with

The study in 1993 of a pulsed laser evaporated boron reaction with ethyne in argon matrix discovered the formation of the borirene radical BC2H2 (48) among other cyclic and linear products (Equation (1)) (93JA2510, 93JPC5839). The reaction was monitored by matrix IR spectra, and the radical (49) is photosensitive and forms spontaneously on annealing above 18 K. The excellent... [Pg.341]

Boron Reaction with curcumin, forming red rosocyanine... [Pg.806]

The "allyl shift" in accordance with an Sf2 process is typical for all 2-alkenylborane or -boronate reactions with electrophiles unless ate complexes get involved. This also holds for protodeborylations. The metalation of a 2-alkene or cycloalkene with a superbase followed by condensation with a boric ester or fluorodimethoxyborane and acidification results in the "counterthermodynamic" transformation of an internal into a terminal olefin (Scheme 1-19). ... [Pg.24]

Methods of producing B —C bonds include hydroboration, nucleophilic displacement at a boron atom in BX., (X = halogens or B(0R>3) by e.g. a Grignard reagent, and a psewiio-Friedel-Crafts reaction with an aromatic hydrocarbon, BX3, and AICI3. [Pg.289]

Concerning my research during my Dow years, as I discuss iu Chapter 4, my search for cationic carbon intermediates started back in Hungary, while 1 was studying Friedel-Crafts-type reactions with acyl and subsequently alkyl fluorides catalyzed by boron trifluoride. In the course of these studies I observed (and, in some cases, isolated) intermediate complexes of either donor-acceptor or ionic nature. [Pg.72]

When mixed with Lewis acids, dinitrogen pentoxide yields crystalline white solids, which were identified as the corresponding nitronium salts by their infra-red spectra. The reaction with boron trifluoride can be formulated in the following way... [Pg.51]

One of the first applications of this technique was to the enrichment of and "B isotopes, present as 18.7 and 81.3 per cent, respectively, in natural abundance. Boron trichloride, BCI3, dissociates when irradiated with a pulsed CO2 laser in the 3g vibrational band at 958 cm (vj is an e vibration of the planar, D j, molecule). One of the products of dissociation was detected by reaction with O2 to form BO which then produced chemiluminescence (emission of radiation as a result of energy gained by chemical reaction) in the visible region due to A U — fluorescence. Irradiation in the 3g band of BCls or "BCI3 resulted in °BO or BO chemiluminescence. The fluorescence of °BO is easily resolved from that of "BO. [Pg.376]

Boron trifluoride is used for the preparation of boranes (see Boron compounds). Diborane is obtained from reaction with alkafl metal hydrides organoboranes are obtained with a suitable Grignard reagent. [Pg.162]

Aromatics containing electron releasing groups such as phenols, dim ethyl am in oben 2en e and indole are formylated by 2-ethoxy-l,3-dithiolane in the presence of boron trifluoroetherate, followed by hydrolysis (114). The preformed dithiolanium tetrafluoroborate also undergoes Friedel-Crafts reaction with aromatics such as dim ethyl am in oben 2en e and indole (115), and was used to generate dithiolanium derivatives (formyl precursors) from the enoltrimethylsilyl ether derivatives (116). [Pg.559]

Aldehydes aie conveniendy synthetized by the reaction of boronic esters with dichloromethylhthium or (phenylthio)methoxymethylhthium (336,337). The synthesis of medium-ting boracyclane stmctures by stepwise ring enlargement is based on the reaction of B-methoxyboracycles with chloromethylhthium (338). [Pg.318]

The conversion of chiral boronic esters iato optically pure B-aIkyl-9-BBN derivatives followed by reaction with a-bromoketones, a-bromoesters, or a-bromonitriles leads to the homologated P-chiral ketones, esters, and nitriles, respectively (526). [Pg.324]

Although all four tocopherols have been synthesized as their all-rac forms, the commercially significant form of tocopherol is i7//-n7i a-tocopheryl acetate. The commercial processes ia use are based on the work reported by several groups ia 1938 (15—17). These processes utilize a Friedel-Crafts-type condensation of 2,3,5-trimethylhydroquinone with either phytol (16), a phytyl haUde (7,16,17), or phytadiene (7). The principal synthesis (Fig. 3) ia current commercial use iavolves condensation of 2,3,5-trimethylhydroquiQone (13) with synthetic isophytol (14) ia an iaert solvent, such as benzene or hexane, with an acid catalyst, such as ziac chloride, boron trifluoride, or orthoboric acid/oxaUc acid (7,8,18) to give the all-rac-acetate ester (15b) by reaction with acetic anhydride. Purification of tocopheryl acetate is readily accompHshed by high vacuum molecular distillation and rectification (<1 mm Hg) to achieve the required USP standard. [Pg.146]

Preparation. Hexagonal boron nitride can be prepared by heating boric oxide with ammonia, or by heating boric oxide, boric acid, or its salts with ammonium chloride, alkaU cyanides, or calcium cyanamide at atmospheric pressure. Elemental nitrogen does not react with boric oxide even in the presence of carbon, though it does react with elemental boron at high temperatures. Boron nitride obtained from the reaction of boron trichloride or boron trifluoride with ammonia is easily purified. [Pg.220]

Boron Triiodide. Boron ttiiodide is not manufactured on a large scale. Small-scale production of BI from boron and iodine is possible in the temperature range 700—900°C (70—72). Excess I2 can be removed as Snl by reaction with Sn, followed by distillation (71). The reaction of metal tetrahydroborates and I2 is convenient for laboratory preparation of BI (73,74). BI can also by synthesized from B2H and HI in a furnace at 250°C (75), or by the reaction of B with excess Agl or Cul between 450—700°C, under vacuum (76). High purity BI has been prepared by the reaction of I2 with mixtures of boron carbide and calcium carbide at elevated temperatures. [Pg.223]

This carboxyborane can undergo an amine exchange reaction with Hquid ammonia (eq. 7) to yield the boron analogue of glycine, the simplest alpha-amino acid (13). There has been a great deal of work on the pharmacological activity of these amino acid analogues (14). [Pg.261]

Aromatic Aldehydes. Carbon monoxide reacts with aromatic hydrocarbons or aryl haHdes to yield aromatic aldehydes (see Aldehydes). The reaction of equation 24 proceeds with yields of 89% when carried out at 273 K and 0.4 MPa (4 atm) using a boron trifluoride—hydrogen fluoride catalyst (72), whereas conversion of aryl haHdes to aldehydes in 84% yield by reaction with CO + H2 requires conditions of 423 K and 7 MPa (70 atm) with a homogeneous palladium catalyst (73) and also produces HCl. [Pg.53]

Beryllium, calcium, boron, and aluminum act in a similar manner. Malonic acid is made from monochloroacetic acid by reaction with potassium cyanide followed by hydrolysis. The acid and the intermediate cyanoacetic acid are used for the synthesis of polymethine dyes, synthetic caffeine, and for the manufacture of diethyl malonate, which is used in the synthesis of barbiturates. Most metals dissolve in aqueous potassium cyanide solutions in the presence of oxygen to form complex cyanides (see Coordination compounds). [Pg.385]

Among the less widely exploited interconversion processes are those involving thermal reactions with ethyl azidoformate, which convert furan into A-ethoxycarbonyl-A -pyrrolin-2-one, and thiophenes into A-ethoxycarbonylpyrroles (Scheme 96a) (64TL2185). The boron trifluoride catalyzed reaction of l,3-diphenylbenzo[c]furan with A-sulfinylaniline results in the replacement of the oxygen by an iV-phenyl group (Scheme 96b) 63JOC2464). [Pg.142]

The most important reaction with Lewis acids such as boron trifluoride etherate is polymerization (Scheme 30) (72MI50601). Other Lewis acids have been used SnCL, Bu 2A1C1, Bu sAl, Et2Zn, SO3, PFs, TiCU, AICI3, Pd(II) and Pt(II) salts. Trialkylaluminum, dialkylzinc and other alkyl metal initiators may partially hydrolyze to catalyze the polymerization by an anionic mechanism rather than the cationic one illustrated in Scheme 30. Cyclic dimers and trimers are often products of cationic polymerization reactions, and desulfurization of the monomer may occur. Polymerization of optically active thiiranes yields optically active polymers (75MI50600). [Pg.146]

Selectivity in formation of protective groups may also be achieved by a proper choice of reaction conditions and catalyst. Thus formation of the 3-monothioketal from 3,6-diketones is achieved by dilution of the ethane-dithiol-boron trifluoride reaction mixture with acetic acid. 3-Monocyanohydrins are obtained in good yield from 3,20-diketo-(5a)-pregnanes by diluting the exchange reaction with ethanol. Similarly, dilution of the... [Pg.378]

Thioketals are readily formed by acid-catalyzed reaction with ethane-dithiol. Selective thioketal formation is achieved at C-3 in the presence of a 6-ketone by carrying out the boron trifluoride catalyzed reaction in diluted medium. Selective protection of the 3-carbonyl group as a thioketal has been effected in high yield with A" -3,17-diketones, A" -3,20-diketones and A" -3,l 1,17-triones in acetic acid at room temperature in the presence of p-toluenesulfonic acid. In the case of thioketals the double bond remains in the 4,5-position. This result is attributed to the greater nucleophilicity of sulfur as compared to oxygen, which promotes closure of intermediate (66) to the protonated cyclic mercaptal (67) rather than elimination to the 3,5-diene [cf. ketal (70) via intermediates (68) and (69)]." " ... [Pg.392]

Unsubstituted 20-ketones undergo exchange dioxolanation nearly with the same ease as saturated 3-ketones although preferential ketalization at C-3 can be achieved under these conditions. " 20,20-Cycloethylenedioxy derivatives are readily prepared by acid-catalyzed reaction with ethylene glycol. The presence of a 12-ketone inhibits formation of 20-ketals. Selective removal of 20-ketals in the presence of a 3-ketal is effected with boron trifluoride at room temperature. Hemithioketals and thioketals " are obtained by conventional procedures. However, the 20-thioketal does not form under mild conditions (dilution technique). ... [Pg.398]

The dimethyl acetal (94) is readily prepared from the 22-aldehyde (93) by direct reaction with methanol in the presence of hydrogen chloride. Ena-mines (95) are formed without a catalyst even with the poorly reactive piperidine and morpholine.Enol acetates (96) are prepared by refluxing with acetic anhydride-sodium acetate or by exchange with isopropenyl acetate in pyridine.Reaction with acetic anhydride catalyzed by boron trifluoride-etherate or perchloric acid gives the aldehyde diacetate. [Pg.401]

A direct method for introduction of a C-21 acetoxyl group into a 20-keto-pregnane is by reaction with lead tetraacetate at room temperature. Although originally the reaction carried out in hot acetic acid gave low yields, a careful study by Henbest has defined conditions so that yields as high as 86 % can be obtained at room temperature. The preferred solvent is 5 % methanol in benzene, with boron trifluoride etherate as catalyst. With either methanol or benzene, the yield is less than 4%. [Pg.203]

A valuable extension of the diazomethane reaction for the preparation of A-homosteroids was discovered by Johnson, Neeman and Birkeland " who found that a,j5-unsaturated ketones are homologated by reaction with diazomethane in the presence of either fluoroboric acid or boron trifluoride. The main product is formed by the insertion of a methylene group between the carbonyl group and the unsaturated a-carbon to give a / ,y-unsaturated ketone. [Pg.361]

These products are thermally stable at room temperature but decompose at elevated temperatures by ehtmnation of CFj The reaction with hydrogen fluonde IS different from that with hydrogen chlonde and hydrogen bromide Presumably this difference is derived from the strength of the boron-fluonne bond [108 (equauon 86)... [Pg.603]

Rate constants have been measured for the reactions of boron compounds with a series of bromomethanes and bromofluoromethanes. Previously it was shown that the reactivity of the chlorine in chlorofluoromethane is substantially reduced by increasing fluorine substitution. The corresponding decrease in the reactivity of bromolluoromethane u as not observed [ifS]. [Pg.608]

Oxiranes exhibit 1,3 [e,n] capacity. Therefore, seven-membered ring systems can be synthesized on reaction with hetero-1,3-dienes. The reaction is catalyzed by 4-dimethylaminopyridine. On catalysis with boron trifluonde, the regioche-mistry is reversed [263] (equation 58). [Pg.874]


See other pages where Boron reactions with is mentioned: [Pg.60]    [Pg.8]    [Pg.25]    [Pg.143]    [Pg.153]    [Pg.981]    [Pg.103]    [Pg.58]    [Pg.39]    [Pg.308]    [Pg.319]    [Pg.324]    [Pg.451]    [Pg.74]    [Pg.265]    [Pg.607]    [Pg.349]    [Pg.55]    [Pg.744]   


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1.3- Diols via reaction of epoxides with boron-stabilized

2-Aminobiphenyl, reaction with boron

2-Aminobiphenyl, reaction with boron trichloride

Aldehydes reactions with boron-stabilized carbanions

Aldol reactions With boron enolates

Aliphatic reactions with boron-stabilized carbanions

Alkenes via reaction of boron-stabilized carbanions with

Ammonia reaction with boron trifluoride

Anisole reaction with boron tribromide

Benzophenone reactions with boron stabilized carbanions

Benzylic boron, reaction with aldehydes

Borane reaction with boron trichloride

Boron bromide reaction with

Boron bromides reactions with alkenes

Boron chloride reaction with, phosgene

Boron compounds, allylconfigurational stability reactions with chiral a-methyl aldehydes

Boron doping reaction with

Boron enolates reactions with aldehydes

Boron fluoride etherate, reaction with

Boron fluoride etherate, reaction with ether and epichlorohydrin

Boron fluoride reaction with, phosgene

Boron halides reactions with

Boron hydride, reaction with alkynes

Boron hydrides reactions with

Boron oxide reaction with

Boron reaction with, phosgene

Boron sulfides reactions with

Boron trichloride reaction with hydrogen

Boron trichloride, reaction with 2aminobiphenyl

Boron trifluoride allylsilane reactions with acetals

Boron trifluoride allylstannane reactions with aldehydes

Boron trifluoride reaction with

Boron trifluoride reaction with allylsilanes, diastereoselectivity

Boron trifluoride reaction with diethyl ether

Boron trifluoride reactions with hydrides

Boron trifluoride reactions with organocopper compounds

Boron, diboron compounds reaction with

Boron, vapor reactions with

Boron-mercury bonds reactions with

Boron-nitrogen bonds reactions with

Boron-stabilized reactions with epoxides

Boron-stabilized reactions with metal halides

Boronates, reactions with oximes

Boronation reaction

Boronic acid, a-chloroallylmismatched diastereoselective reactions with

Boronic acid, a-chloroallylmismatched diastereoselective reactions with aldehydes

Boronic acid, a-chlorocrotyldiastereofacial preference reactions with aldehydes

Boronic acid, allylesters reactions with a-methyl chiral aldehydes

Boronic acid, allylesters reactions with achiral aldehydes

Boronic acid, allylesters reactions with aldehydes

Boronic acid, allylesters reactions with aldoximes

Boronic acid, allylesters reactions with imines

Boronic acid, allylesters reactions with ketones

Boronic acid, allylesters reactions with sulfenimides

Boronic acid, crotylchiral reactions with achiral aldehydes

Boronic acid, crotylchiral reactions with aldehydes

Boronic acid, crotylchiral reactions with chiral aldehydes

Boronic acid, crotylchiral reactions with oxime silyl ethers

Boronic acid, crotylchiral stereoselective reactions with aldehydes

Boronic acids reaction with aryl triflates

Boronic acids reaction with halogens

Boronic esters reaction with halogen

Boronic esters reaction with organolithium reagents

Boron—carbon bonds reactions with

Boron—carbon bonds reactions with hydrogen

Boron—oxygen bonds reactions with

Boron—phosphorus bonds reaction with

Boron—sulfur bonds reactions with

Carbonyl compounds reaction with boron reagents

Cobalt-boron bonds reactions with

Cross coupling reactions aryl boronic acids with amines

Cyclohexanones reactions with boron stabilized carbanions

Elemental boron reactions with

Enolates, boron reactions with imines

Epichlorohydrin reaction with boron trifluoride ether

Epichlorohydrin reaction with boron trifluoride etherate to form triethyloxonium fluoborate

Heck reaction, with boronic acids

Imine reaction with boronic acid derivative

Ketenes reaction with boron reagents

Ketones reactions with boron-stabilized carbanions

Ketones, reaction with boron enolates

Oximes reactions with crotyl boronates

Radical addition reactions with boron compounds

Reaction of Other Pentacarbonylcarbene Complexes with Boron Trihalides

Reaction of Phenylmagnesium Bromide with Boronic Acid Trimethyl Ester

Reaction with boronic esters

Reactions Boron

Reactions of boron and aluminum hydrides with other coordinated ligands

Reactions with Boron Compounds

Reactions with Sulfur, Boron, Carbon, Phosphorus, Arsenic, Antimony, and Bismuth

Reactions with aldehydes boron-mediated

Reactions with boron enolates

Recent Advances in Copper-promoted C-Heteroatom Bond Cross-coupling Reactions with Boronic Acids and Derivatives

Silver oxide, reaction with boron

Silver oxide, reaction with boron alkyls

Synthesis reaction with boron reagents

Trichloride, boron reaction with diborane

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