Alcohols, 3-alkoxy synthesis

Synthesis. Titanium alkoxy halides are intermediates in the preparation of alkoxides from a titanium tetrahaUde (except the fluoride) and an alcohol or phenol. If TiCl is heated with excess primary alcohol, only two chlorine atoms can be replaced and the product is dialkoxydichlorotitanium alcoholate, (RO)2TiCl2 ROH. The yields are poor, and some alcohols, such as aHyl, ben2yl, and /-butyl alcohols, are converted to chlorides (46). Using excess TiCl at 0°C, the trichloride ROTiCl is obtained nearly quantitatively, even from sec- and / f/-alcohols (47,48). 

An asymmetric synthesis has used the reduction of imonium salts to optically active tertiary amines with lithium aluminum alkoxy hydrides derived from optically active alcohols (538,539). 

An acid-catalyzed substitution of a 6-oxo group on 2-aminopteridine-4,6-dione with hydrogen chloride in alcohols (65-100°, 3 hr, 80% yield) represents a convenient synthesis of the 6-alkoxy analogs. The reaction proceeds also with pteridine-2,4,6-trione and its 1-methyl and 1,3-dimethyl derivatives. While methoxylation of 2,4,7-trichloro-quinoline gives about equal amounts of 2- and 4-substitution, acid-catalyzed hydrolysis gives specific reaction at the 2-position only. ... 

The oxacarbene in (2.1) is usually trapped by water or an alcohol to give hydroxy- or alkoxy tetrahydrofuran derivatives. This sequence has been connected with the synthesis of prostaglandines (2.3) 206). 

The preference for the /3-silyl isomer product complements methods available for hydrostannation of alkynes, for which the a-stannyl regioisomer is formed preferentially.70 7011 70c In addition, the /3-silyl products serve as the platform for a tertiary alcohol synthesis (Scheme 15). Upon treatment of vinylsilanes such as B with tetrabutylam-monium fluoride (TBAF) in DMF at 0 °C, a 1,2 carbon-to-silicon migration occurs, affording the tertiary heterosilane E. Oxidation of the C-Si bond then provides the tertiary alcohol. Good 1,2-diastereocontrol has been demonstrated for y-alkoxy substrates, as in the example shown. The studies suggest that the oxidation of the sterically demanding silane intermediate is facilitated by the intramolecular formation of a silyl hemiketal or silyllactone for ketone or ester substrates, respectively.71... 

Many of the characterization techniques described in this chapter require ambient or vacuum conditions, which may or may not be translatable to operational conditions. In situ or in opemndo characterization avoids such issues and can provide insight and information under more realistic conditions. Such approaches are becoming more common in X-ray adsorption spectroscopy (XAS) methods ofXANES and EXAFS, in NMR and in transmission electron microscopy where environmental instruments and cells are becoming common. In situ MAS NMR has been used to characterize reaction intermediates, organic deposits, surface complexes and the nature of transition state and reaction pathways. The formation of alkoxy species on zeolites upon adsorption of olefins or alcohols have been observed by C in situ and ex situ NMR [253]. Sensitivity enhancement techniques play an important role in the progress of this area. In operando infrared and RAMAN is becoming more widely used. In situ RAMAN spectroscopy has been used to online monitor synthesis of zeolites in pressurized reactors [254]. Such techniques will become commonplace. 

Ethers may be prepared by (1) dehydration of alcohols and (11) Williamson synthesis. The boiling points of ethers resemble those of alkanes while their solubility Is comparable to those of alcohols having same molecular mass. The C-O bond In ethers can be cleaved by hydrogen halides. In electrophilic substitution, the alkoxy group activates the aromatic ring and directs the Incoming group to ortho and para positions. 

The double bond of certain a,p-unsaturated esters (e.g. crotonates, methacrylates) is so reactive that it tends to add the elements of the alcohol present as solvent the resulting p-alkoxy-substituted guanamines (LXXXV) (79) are therefore readily and cheaply produced, and the use of expensive p-alkoxycarboxylic esters required in the conventional synthesis (706) is avoided. Crotonic esters give the alkoxyguanamine... 

We then studied group 5 metals, especially tantalum-for which the laboratory already had great experience. Because of the studied reaction, alkyl or hydride-type compounds such as those developed in the laboratory could not be employed. Consequently, we became interested in alkoxo-type derivatives, either synthesized by reaction of the grafted complex with an alcohol or obtained by direct synthesis starting from an alkoxy-tantalum compound grafted on silica. In all cases, resulting complexes have been characterized by surface organometallic chemistry techniques, especially EXAFS and solid-state NMR (ID and 2D with C-labeled compounds). Indeed various compounds bonded by one, two or three surface bonds have been prepared and characterized. 

Ojima and coworkers have developed a similar approach to the synthesis of piperidine and related ring systems, which they describe as cyclohydrocarbonylation. In this approach, carbamate-protected allylglydnes (for example, 32) are subjected to rho-dium(I)-catalyzed hydroformylation in an alcohol solvent (Scheme 5.13) [17]. 6-Alkoxy-pipecolates 33 are isolated in good yield and were shown to be amenable to further stereoselective transformations. This methodology has recently been expanded to include fully intramolecular variants that can form two rings in a single reaction. Thus, alkenes 34 are subjected to the cyclohydrocarbonylation conditions to provide azabicy-clo[4.4.0]aUcane amino acids 35 which can serve as conformationaUy restricted dipeptide surrogates and /9-turn mimetics [18]. 

Af-Acyloxy-Al-alkoxyureas and carbamates (equation 9, R = NR2, RO) have been generated similarly in MeCN . Earlier, the same group described the synthesis of N,N-dialkoxyureas (76) from the reaction of Al-alkoxy-V-chloroureas (75) with sodium alkox-ides in the corresponding alcohol (equation 10) Properties of Af,Af-dialkoxyamides and -ureas and -carbamates are described in Section V. 

Z- and 4-alkoxyquinazolines are readily prepared by nucleophilic substitution reactions, and 2,4-dialkoxyquinazolines can simply be prepared by boiling 2,4-dichloroquinazolines with 2 equiv of an alkoxide in the appropriate alcohol solvent <1996HC(55)1>. The first substitution is in the more reactive 4-position, so it is possible to isolate both 4-alkoxy and 4-phenoxy monosubstitution products <1977EJM325, 2005BMC3681>, and this selectivity has been used to attach both 2,4,6- and 2,4,7-trichloroquinazoline to a solid support, via the 4-position, for subsequent solid-phase synthesis of 2,6- and 2,7-diamino-4(377)-quinazolinones <2003TL7533>. 

Two different methods have also been described for the synthesis of 4-alkoxy-5(2//)-oxazolones 50. In the first case, 4-(phenylthio)-5(277)-oxazolones 48 are oxidized to the 4-phenylsulfinyl derivatives that react with the alcohol present in the reaction medium to afford the corresponding 4-alkoxy derivatives. Alternatively, 4-alkoxy-5(2//)-oxazolones 50 have been obtained by condensation of iminooxalates and ketones in acidic medium. (Scheme 7.12 Table 7.7, Fig. 7.8 Table 7.8, Fig. 7.9). 

---