Alkylation with methanol

Formamide has been alkylated with methanol ia the presence of a metal catalyst to give DMF (22). The alkylation reaction can also be catalyzed by tetralkylammonium salts (23). 

Mel, CH3CN morpholine or diethylamine, methanol, 76-95% yield. These conditions also cleave tlie 4 -pyridyl derivative. The Pet ester is stable to the acidic conditions required to remove the BOC and r-butyl ester groups, to the basic conditions required to remove the Fmoc and Fm groups, and to hydrogenolysis. It is not recommended for use in peptides that contain methionine or histidine since these are susceptible to alkylation with methyl iodide. 

Iron porphyrins containing vinyl ligands have also been prepared by hydromet-allation of alkynes with Fe(TPP)CI and NaBH4 in toluene/methanol. Reactions with hex-2-yne and hex-3-yne are shown in Scheme 4. with the former giving two isomers. Insertion of an alkyne into an Fe(III) hydride intermediate, Fe(TPP)H, formed from Fe(TPP)Cl with NaBH4, has been proposed for these reactions. " In superficially similar chemistry, Fe(TPP)CI (present in 10 mol%) catalyzes the reduction of alkenes and alkynes with 200 mol% NaBH4 in anaerobic benzene/ethanol. For example, styrene is reduced to 2,3-diphenylbutane and ethylbenzene. Addition of a radical trap decreases the yield of the coupled product, 2,3-diphenylbutane. Both Fe(lll) and Fe(II) alkyls, Fe(TPP)CH(Me)Ph and [Fe(TPP)CH(Me)Ph] , were propo.sed as intermediates, but were not observed directly. ... 

Certain quaternary ammonium salts will alkylate [Co (DMG)2py] . The addition of PhCH2NMc3 I to a solution of the complex in methanol gives the PhCH2Co complex in 45% yield. The reaction works more slowly with dimethylpiperidinium iodide to give the CH3—Co complex 15). There is no alkylation with tertiary amines alone 164), but in the presence of equimolar amounts of dimethylacetylenedicarboxylate certain aliphatic tertiary amines can alkylate [Co (DMG)2py] in methanol solution. The reaction also produces the enamine derivative of a maleic ester, and the mechanism appears to involve addition of the amine to the triple bond to form an ammonium salt, which can then attack the Co(I) derivative (75). 

Since their development in 1974 ZSM-5 zeolites have had considerable commercial success. ZSM-5 has a 10-membered ring-pore aperture of 0.55 nm (hence the 5 in ZSM-5), which is an ideal dimension for carrying out selective transformations on small aromatic substrates. Being the feedstock for PET, / -xylene is the most useful of the xylene isomers. The Bronsted acid form of ZSM-5, H-ZSM-5, is used to produce p-xylene selectively through toluene alkylation with methanol, xylene isomerization and toluene disproportionation (Figure 4.4). This is an example of a product selective reaction in which the reactant (toluene) is small enough to enter the pore but some of the initial products formed (o and w-xylene) are too large to diffuse rapidly out of the pore. /7-Xylene can, however. 

The purpose of this work was to increase the A3 selectivity at low conversion through a catalyst modification. Previous studies of phenol alkylation with methanol (the analogue reaction) over oxides and zeolites showed that the reaction is sensitive to acidic and basic properties of the catalysts [3-5]. It is the aim of this study to understand the dependence of catalyst structure and acidity on activity and selectivity in gas phase methylation of catechol. Different cations such as Li, K, Mg, Ca, B, incorporated into y-Al203 can markedly modify the polarisation of the lattice and consequently influence the acidic and basic properties of the surface [5-8] which control the mechanism of this reaction. 

Ethylenethiourea (ETU) is a toxic decomposition product/metabolite of alky-lenebis(dithiocarbamates). This compound could be generated during processing of treated crops at elevated temperature. Different chromatographic methods to determine the residue levels of ETU have been published. After extraction with methanol, clean-up on a Gas-Chrom S/alumina column and derivatization (alkylation) with bro-mobutane, ETU residues can be determined by GC with a flame photometric detector in the sulfur mode. Alternatively, ETU residues can also be determined by an HPLC method with UV detection at 240 nm or by liquid chromatography/mass spectrometry (LC/MS) or liquid chromatography/tandem mass spectrometry (LC/MS/MS) (molecular ion m/z 103). ... 

In this regard Gedye et al. studied reactions of alkyl halides with bases in which the amounts of elimination and substitution were compared and a Diels-Alder reaction in which the ratio of endo to exo adducts was investigated [71]. In the first set of experiments, the ratios of elimination to substitution products for the reactions of 1-and 2-bromooctane with methoxide ion in methanol and with tert-butoxide ion in tert-butyl alcohol, obtained under MW heating in a sealed Teflon container, were compared with those found using normal reflux conditions (Scheme 4.25). 

While p for the polar effects of alkyl groups does not vary with the solvent, pn for the polar effects of aromatic substituents is solvent-dependent. For example, there is a fairly linear log/log relationship between the bromination rates of styrenes in acetic acid and methanol (36) with a slope higher than unity, to be compared with 0.99 in (24). The p+-value for styrenes... 

In the case of toluene alkylation with methanol an opportunity exists for para selectivity. Para-xylene ortho-xylene ratio was 3.1 over MFl and 0.6 over BEA framework types. 

Tetramethyl-/ -phenylenediamine has been obtained in low yield by the reaction of />-phenylenediamine with various alkylating agents such as methyl iodide, methanol in the presence of hydrochloric acid at 170-200°, or formaldehyde and formic acid. In addition it has been prepared by methylating / -dimethyl-aminoaniline using methanol in the presence of hydrochloric acid at 170 -200°, followed by treatment of the resulting salts with aqueous ammonia at 180 190°. In the most recent >ro-cedure, / -phenyIenediamine was alkylated with sodium chloro-... 

The third synthetic route reported by Husson and co-workers 140) is as follows Amino nitrile 472 obtained from the ketal (471) was converted to the 2,6-dialkylpiperidine (473) by catalytic hydrogenation followed by alkylation with lithium diisopropylamide and pentyl bromide. Refluxing a solution of 473 in methanol containing hydrochloric acid led to the formation of 9-benzyladaline (475) in 90% yield. Debenzylation of 475 gave d/-adaline (107) in nearly quantitative yield (Scheme 59) 140). 

The acidic/basic properties of zeolites can be changed by introdnction of B, In, Ga elements into the crystal framework. For example, a coincorporation of alnminnm and boron in the zeolite lattice has revealed weak acidity for boron-associated sites [246] in boron-snbstitnted ZSM5 and ZSMll zeolites. Ammonia adsorption microcalorimetry gave initial heats of adsorption of abont 65 kJ/mol for H-B-ZSMll and showed that B-substituted pentasils have only very weak acidity [247]. Calcination at 800°C increased the heats of NH3 adsorption to about 170 kJ/mol by creation of strong Lewis acid sites as it can be seen in Figure 13.13. The lack of strong Brpnsted acid sites in H-B-ZSMll was confirmed by poor catalytic activity in methanol conversion and in toluene alkylation with methanol. 

The role of the much discussed "primary reaction" of formation of a C2-hydrocarbon from methanol is then limited to producing a very small amount chemisorbed ethene during the incubation period. This C2 will react easily to C3 via alkylation with methanol. 

Alternatively, the imide-acid chloride is reacted with methanol to give the imide ester which, after borohydride reduction and triethylsilane/trifluoroacetic acid treatment, furnishes the bicyclic lactam 6 as a racemate. The latter is acylated with either propanoyl chloride or 3-phcnylpropanoyl chloride and the resulting amides 7 deprotonated and alkylated with (bro-momethyljbenzene or iodomethane, respectively, to give the major alkylation products 8 with d.r. >98 2 and in 65% yield3. 

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