Dehydrogenation double bonds

The catalytic activity was found to depend on the nature of the metal catalyst. Higher efficiency was obtained with Mo catalysts as compared to Cr and W ones. The nature of the ligand attached to the metal has some control over the conversion. In addition to dehydrogenation double bond migration also takes place. 

Typical base-catalysed reactions that occur over alkali metal-exchanged zeolites include dehydrogenations, double bond isomerisations, side-chain alkylation of aromatics, conversion of methyl halides and a range of condensations. The reaction of alcohols over zeolites can be used to determine whether acid or base catalysis predominates. Whereas acid forms of zeolites catalyse dehydrations, leading to alkenes and the products of their subsequent reactions, basic sites catalyse dehydrogenations, leading to aldehydes and ketones. 

Futhermore, Goldman has found a complex that features a pincer ligand and is the most efficient catalyst for alkane dehydrogenation.Double bonds can be introduced into polymers and dehydrogenation of tertiary amines leads to enamines. ... 

The biological dehydrogenation of succinic acid described in Section 5 8 is 100% stereoselective Only fumaric acid which has a trans double bond is formed High levels of stereoselectivity are characteristic of enzyme catalyzed reactions... 

Megestrol acetate (79) is stmcturaHy related to progesterone (1). It has been prepared from medroxyprogesterone acetate (74) by chloranil-mediated dehydrogenation. It also has been prepared from hydroxyprogesterone acetate (42) via 6-methylenation and double-bond migration (109,110). 

The dehydrogenation of 4-aryl quinolizidines is very interesting, too. The double bond of the salts is formed in the position and not in the expected position (127). In several cases, hydroxylation takes place in the dehydrogenation of 1-methylquinolizidine (115), especially of cis-and rfl/i5-l-methyldecahydroquinolines (128,129) (Scheme 5). 

Enamines derived from 1-azabicycloalkanes, readily accessible by mercuric acetate oxidation of saturated bases (112), have been extensively studied recently (113-115). Since an immonium salt is formed during dehydrogenation, the composition of the liberated enamine mixture shows the relative stability of the various possible isomers. The study of infrared and NMR spectra has shown that the position of the enamine double bond is determined by factors similar to those determining the relative stability of simple olefins. 

The enamine formed by dehydrogenation of indollzidine was considered to be a mixture of Zl (54) and Zl (55) isomers because of infrared spectra (126). According to the NM R spectrum, the A isomer Isthe majorconstituent. This is demonstrated by comparison of this spectrum with the spectra of compounds 56 and 57 containing fixed double bonds. 

The addition of double bonds to fatty acids in eukaryotes does not occur until the fatty acyl chain has reached its full length (usually 16 to 18 carbons). Dehydrogenation of stearoyl-CoA occurs in the middle of the chain despite the absence of any useful functional group on the chain to facilitate activation ... 

This impressive reaction is catalyzed by stearoyl-CoA desaturase, a 53-kD enzyme containing a nonheme iron center. NADH and oxygen (Og) are required, as are two other proteins cytochrome 65 reductase (a 43-kD flavo-protein) and cytochrome 65 (16.7 kD). All three proteins are associated with the endoplasmic reticulum membrane. Cytochrome reductase transfers a pair of electrons from NADH through FAD to cytochrome (Figure 25.14). Oxidation of reduced cytochrome be, is coupled to reduction of nonheme Fe to Fe in the desaturase. The Fe accepts a pair of electrons (one at a time in a cycle) from cytochrome b and creates a cis double bond at the 9,10-posi-tion of the stearoyl-CoA substrate. Og is the terminal electron acceptor in this fatty acyl desaturation cycle. Note that two water molecules are made, which means that four electrons are transferred overall. Two of these come through the reaction sequence from NADH, and two come from the fatty acyl substrate that is being dehydrogenated. 

These pentahydrides have attracted attention as catalysts for hydrogenation of the double bond in alkenes. IrH5(PPr3)2 catalyses vinylic H-D exchange between terminal alkenes and benzene, the isomerization of a,f3-ynones, isomerization of unsaturated alcohols and dehydrogenation of molecules such as secondary alcohols [176],... 

The first step in this preparation, the epoxidation of 1,4,5,8-tetra-hydronaphthalene, exemplifies the well-known selectivity exerted by peracids in their reaction with alkenes possessing double bonds that differ in the degree of alkyl substitution.12 As regards the method of aromatization employed in the conversion of ll-oxatricyclo[4.4.1.01-6]-undeca-3,8-diene to l,6-oxido[10]annulene, the two-step bromination-dehydrobromination sequence is given preference to the one-step DDQ-dehydrogenation, which was advantageously applied in the synthesis of l,6-metliano[10]annulene,2,9 since it affords the product in higher yield and purity. 

On one hand, /z-alkanes of the molecular range C10-C16 are important starting materials for the synthesis of anionic surfactants. It is possible to dehydrogenate these hydrocarbons to isomeric /z-olefins with internal double bonds olefins) [4], which are also important initial products for the synthesis of an-... 

Not only the linear Cl0-Cl8 a-olefins but also the linear C10-Cl8 olefins with internal double bonds, the so-called -v /-olefins, are of great importance in surfactant chemistry, n-a-Olefins and n-y-olefins have the same suitability for the manufacture of linear alkylbenzenes, the most important synthetic anionic surfactants, by alkylation of benzene. Nowadays medium molecular weight n- /-olefins are industrially produced by two processes the catalytic dehydrogenation of the corresponding n-alkanes [4,28] and the cometathesis of low and high molecular weight n-v /-olefins, obtained by double-bond isomerization of the isomeric n-a-olefins [29]. 

Dehydrogenations Yielding Carbon-Carbon Double Bonds... 

The onward metabohsm of succinate, leading to the regeneration of oxaloacetate, is the same sequence of chemical reactions as occurs in the P-oxidation of fatty acids dehydrogenation to form a carbon-carbon double bond, addition of water to form a hydroxyl group, and a hirther dehydrogenation to yield the oxo- group of oxaloacetate. 

Nickel metal successfully catalyzes the hydrogenation of double bonds in unsaturated hydrocarbons such as propylene and butene. Can this metal also catalyze the dehydrogenation of alkanes such as propane and butane ... 

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