1.1- Dialkyl alkenes

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. 

Even the use ofperfluorinated alkenes, dialkyl ethers, etc., (ormingfluorous biphase systems because of their low miscibility with common organic solvents such as acetone, toluene, THE, and alcohols, is a subdivision of biphasic catalysis and. 

Alkenes. The sulfation of low molecular weight alkenes using concentrated sulfuric acid is amenable to continuous operation. Good agitation is required and the reaction is performed at 70—80°C. Dialkyl sulfates ate also formed. Longer (C 2 i8) carbon chain alkenes yield detergent products. Order... 

Detergents have been manufactured from long-chain alkenes and sulfuhc acid, especially those obtained from shale oil or cracking of petroleum wax. These are sulfated with 90—98 wt % acid at 10—15°C for a 5-min contact time and at an acid—alkene molar ratio of 2 1 (82). Dialkyl sulfate initially forms when 96 wt % acid is added to 1-dodecene at 0°C, but it is subsequently converted to the hydrogen sulfate in 80% yield upon the further addition of sulfuhc acid. The yield can be increased to 90% by using 98 wt % sulfuhc acid and pentane as the solvent at -15°C (83). 

Formation of Sulfides. Thiols react readily with alkenes under the same types of conditions used to manufacture thiols. In this way, dialkyl sulfides and mixed alkyl sulfides can be produced. Sulfides are a principal by-product of thiol production. Mixed sulfides can be formed by the reaction of the thiol using a suitable starting material, as shown in equations 21, 22, and 23. Vinyl sulfides can be produced by the reaction of alkynes with thiols (38). 

The above cycloaddition process consists of two separate [3-1-2] cycloaddition steps and represents a 1,3-2,4 addition of a multiple bond system to a hetero-1,3-diene [7S7]. The structure ot the azomethine imine intermediate has been proved unequivocally by X-ray analysis [195] Ethylene [194], acetylene [/iS2] . many alkyl- and aryl- as well sgemmal dialkyl- and diaryl-substituted alkenes [196,197, 198, 199], dienes [200], and alkynes [182, 201], certain cyclic alkenes [198, 199,... 

Higher trialkyls are more readily prepared on an industrial scale by the alkene route (K. Ziegler et al., I960) in which H2 adds to Al in the presence of preformed AIR3 to give a dialkyl-aluminium hydride which then readily adds to the alkene ... 

Alkene complexes Alkynyl complexes Ammine complexes Aqueous chemistry Arsine complexes Auranofin Auride ion Aurophilicity Binary compounds Bond lengths acetylacetonate complex alkyls and aryls ammine complexes carboxylates cyanide complexes dialkyl sulphide complexes dithiocarbamates to gold... 

A method for the stereospecific synthesis of thiolane oxides involves the pyrolysis of derivatives of 5-t-butylsulfinylpentene (310), and is based on the thermal decomposition of dialkyl sulfoxides to alkenes and alkanesulfenic acids299 (equation 113). This reversible reaction proceeds by a concerted syn-intramolecular mechanism246,300 and thus facilitates the desired stereospecific synthesis301. The stereoelectronic requirements preclude the formation of the other possible isomer or the six-membered ring thiane oxide (equation 114). Bicyclic thiolane oxides can be prepared similarly from a cyclic alkene301. 

Di-f-butyl sulfone is different from the other dialkyl sulfones in that RH is mainly alkene and not alkane [G(isobutene) = 3.2 and G(isobutane) = 1.2]. The preference for isobutene over isobutane means that the formation of the alkene cannot be due to disproportionation of two t-butyl radicals but is due to a hydrogen atom expulsion as suggested by Bowmer and O Donnell70... 

Dialkyl-[alken-(l)-yl]-borane werden nach Uberfiihrung mit Alkyl-lithium in die Lithium-trialkyl-[alken-(l)-yI]-borate bereits mit 6 n Natronlauge bei 20° hydrolysiert5. 

Selektive Protonolyse der Dialkyl-[alken-(l)-yl]-aluminium-Verbindungen wird durch Zugabe einer Kohlenwasscrstoff-Losung (z.B. Toluol) von Pentandion-(2,4) bei —30° bis 0° erreicht3 ... 

Polyfluor-alkene werden durch Dialkyl-zinndihydride hydrostanniert8 bzw. stu-fenweise reduziert J z. B. ... 

Die partielle Reduktion von Alkinen zu Alkenen durch Chrom(ll)-L6sungen in ammoniakalischer Ammoniumchlorid- Oder salzsaurer Losung ist nur teilweise moglich. Wahrend Acetylen, Alkyl- und Aryl-al-kine Alkene bildcn, wcrden Dialkyl-alkine nicht angegriffen (s. Bd. V/lb, S. 584). Die durch Reduktion mit Chrom(II)-sulfat entstehenden Alkene besitzen uberwicgend(ran.v-Konfiguration (80-90% d.Th. s. Bd. V/lb, S. 783, vgl. auch 584). 

The groups R2N and Cl can be added directly to alkenes, allenes, conjugated dienes, and alkynes, by treatment with dialkyl-V-chloroamines and acids. " These are free-radical additions, with initial attack by the R2NH- radical ion. " N-Halo amides (RCONHX) add RCONH and X to double bonds under the influence of UV light or chromous chloride. " Amines add to allenes in the presence of a palladium catalyst. ... 

Asymmetric epoxidation is another important area of activity, initially pioneered by Sharpless, using catalysts based on titanium tetraisoprop-oxide and either (+) or (—) dialkyl tartrate. The enantiomer formed depends on the tartrate used. Whilst this process has been widely used for the synthesis of complex carbohydrates it is limited to allylic alcohols, the hydroxyl group bonding the substrate to the catalyst. Jacobson catalysts (Formula 4.3) based on manganese complexes with chiral Shiff bases have been shown to be efficient in epoxidation of a wide range of alkenes. 

The hydroaminations of electron-deficient alkenes with aniline or small primary alkylamines proceed at high conversions (85-95%, nnder mild conditions, 5 mol%, rt), giving exclnsively the anh-Markovnikov addition product. Secondary dialkyl or bnlky primary amines require longer reaction times. With amines containing P-hydrogens, no imine side-products were observed. 

As in the P(III) chemistry above, both late metal (Pd) and lanthanide catalysts have been used for P(V)-H additions to alkynes, alkenes, aldehydes, and imines. In addition, titanium, aluminum, and zinc catalysts have been employed. Typical P(V) substrates include dialkyl phosphites P(0R)2(0)H and phosphine oxides PR2(0)H. 

Among recently described new Pd-catalysed enantioselective reactions, the ring opening of meso oxabicyclic alkenes with dialkyl zinc reagents in the presence of chiral P/P and P/N ligands reported by Tautens el al. constitutes a synthetically outstanding C-C bond-forming desymmetrization reaction. 

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