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Acid-catalyzed reactions group

Acid-C t lyzed Chemistry. Acid-catalyzed reactions form the basis for essentially all chemically amplified resist systems for microlithography appHcations (61). These reactions can be generally classified as either cross-linking (photopolymerization) or deprotection reactions. The latter are used to unmask acidic functionality such as phenohc or pendent carboxyhc acid groups, and thus lend themselves to positive tone resist apphcations. Acid-catalyzed polymer cross-linking and photopolymerization reactions, on the other hand, find appHcation in negative tone resist systems. Representative examples of each type of chemistry are Hsted below. [Pg.125]

As chemists proceeded to synthesize more complicated stmctures, they developed more satisfactory protective groups and more effective methods for the formation and cleavage of protected compounds. At first a tetrahydropyranyl acetal was prepared, by an acid-catalyzed reaction with dihydropyran, to protect a hydroxyl group. The acetal is readily cleaved by mild acid hydrolysis, but formation of this acetal introduces a new stereogenic center. Formation of the 4-methoxytetrahy-dropyranyl ketal eliminates this problem. [Pg.2]

Me2C(OMe)2, DMF, pyridinium p-toluenesulfonate (PPTS). The use of PPTS for acid-catalyzed reactions has been quite successful and is particularly useful when TsOH acid is too strong an acid for the functionality in a given molecule. TBDMS groups are stable under these conditions. [Pg.124]

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]

B-Homosteroids have also been prepared by acid-catalyzed reaction of diazomethane with a,/5-unsaturated ketones. 3/ -Hydroxycholest-5-en-7-one acetate (57) reacts with diazomethane in the presence of concentrated fluoroboric acid, boron trifluoride etherate or aluminum chloride to give 3yS-hydroxy-B-homo-cholest-5-en-7a-one acetate (67). The 7a-keto group is reported to be chemically less reactive than an 11-keto group. [Pg.378]

The acid-catalyzed reaction of acetophenone with acyclic secondary amines results in the formation of the expected enamine and a rearrangement product. The latter product arises from the transfer of one of the amino N-alkyl groups to the cnamine s carbon to produce a ketimine (53a). [Pg.68]

The 0X0 group, will tend to activate nucleophihc substitution when its oxygen atom is protonated (e.g., 201 when Z is H) in acid-catalyzed reactions 223b,298 qj. hydrogen bonding to the solvent. Acceleration... [Pg.245]

The Prins reaction often yields stereospecifically the and-addition product this observation is not rationalized by the above mechanism. Investigations of the sulfuric acid-catalyzed reaction of cyclohexene 8 with formaldehyde in acetic acid as solvent suggest that the carbenium ion species 7 is stabilized by a neighboring-group effect as shown in 9. The further reaction then proceeds from the face opposite to the coordinating OH-group " ... [Pg.233]

The acid-catalyzed reaction occurs by an electrophilic substitution where formaldehyde is the electrophile. Condensation between the methylol groups and the benzene rings results in the formation of methylene bridges. Usually, the ratio of formaldehyde to phenol is kept less than unity to produce a linear fusible polymer in the first stage. Crosslinking of the formed polymer can occur by adding more formaldehyde and a small amount of hexamethylene tetramine (hexamine. [Pg.347]

Acid-catalyzed reaction of an aldehyde or ketone with 2 equivalents of a monoalcohol or 1 equivalent of a diol yields an acetal, in which the carbonyl oxygen atom is replaced by two -OK groups from the alcohol. [Pg.720]

Basic hydrolysis occurs by nucleophilic addition of OH- to the amide carbonyl group, followed by elimination of amide ion (-NH2) and subsequent deprotonation of the initially formed carboxylic acid by amide ion. The steps are reversible, with the equilibrium shifted toward product by the final deprotonation of the carboxylic acid. Basic hydrolysis is substantially more difficult than the analogous acid-catalyzed reaction because amide ion is a very poor leaving group, making the elimination step difficult. [Pg.815]

Danshefsky s diene [19] is the 1,3-butadiene with amethoxy group at the 1-position and a trimethylsiloxy group at the 3-position (Scheme 18). This diene and Lewis acids extended the scope of hetereo-Diels-Alder reactions with aldehydes [20], This diene reacts with virtually any aldehyde in the presence of Lewis acids whereas dienes usually react with only selected aldehydes bearing strongly electron accepting a-substituents. There are two (Diels-Alder and Mukaiyama aldol) reaction pathways (Scheme 18) identified for the Lewis acids catalyzed reactions of Danishefsky diene with aldehydes [21, 22]. The two pathways suggest that these reactions occur on the boundary between the delocahzation band (the pericyclic... [Pg.69]

Oae found that for both base- and acid-catalyzed hydrolysis of phenyl benzenesul-fonate, there was no incorporation of 0 from solvent into the sulfonate ester after partial hydrolysis. This was interpreted as ruling out a stepwise mechanism, but in fact it could be stepwise with slow pseudorotation. In fact this nonexchange can be explained by Westheimer s rules for pseudorotation, assuming the same rules apply to pentacoordinate sulfur. For the acid-catalyzed reaction, the likely intermediate would be 8 for which pseudorotation would be disfavored because it would put a carbon at an apical position. Further protonation to the cationic intermediate is unlikely even in lOM HCl (the medium for Oae s experiments) because of the high acidity of this species a Branch and Calvin calculation (See Appendix), supplemented by allowance for the effect of the phenyl groups (taken as the difference in between sulfuric acid and benzenesulfonic acid ), leads to a pA, of -7 for the first pisTa of this cation about -2 for the second p/sTa. and about 3 for the third Thus, protonation by aqueous HCl to give the neutral intermediate is likely but further protonation to give cation 9 would be very unlikely. [Pg.26]

Trialkylsilyl cations may play a key role in other Lewis acid-catalyzed reactions.59 For example, trimethylsilyl triflate can be formed by intermolecular transfer of the silyl group. When this occurs, the trimethylsilyl triflate can initiate a catalytic cycle that does not directly involve the Lewis acid. [Pg.83]

The heterocyclic derivative successfully protects the acid from attack by Grignard or hydride-transfer reagents. The carboxylic acid group can be regenerated by acidic hydrolysis or converted to an ester by acid-catalyzed reaction with the appropriate alcohol. [Pg.275]

The study on 2,7-di-rerf-butylthiepin has recently been extended to explore more simply substituted thiepins 58). The palladium-catalyzed reaction of the diazo compound 107 lacking a 4-methyl substituent gives exclusively the exo-methylene compound 108 whereas the acid-catalyzed reaction of the same precursor 107 resulted in the formation of 2,7-di-/er/-butyl-4-ethoxycarbonylthiepin (109)58). Due to the substantial thermal stability of 109 it is possible to transform the ethoxy-carbonyl group into the hydroxymethyl (110), trimethylsilyloxymethyl (111) and formyl group (112)58). [Pg.55]

The addition of protons to the carbonyl group is an important process because of the role it plays in the acid catalyzed reactions of many types of carbonyl compounds. Because of the difference in electronegativity, it is likely that the proton is associated specifically with the oxygen rather than with the carbonyl group as a whole. [Pg.143]

The base lability of succinoyl diester hnker severely limits the selection of protecting groups available for an oligosaccharide synthesis, so a more versatile tether was required. Diether bonds of benzylphenol or dibenzyl of 1,4-di(hydroxymethyl)-benzene satisfy this requirement because they are stable to both bases and to acids. A sufficient acid stability is important since the formation of a glycosidic bond is an acid-catalyzed reaction, not surprisingly, as it is an acetal functionality. For instance, DOX,34 the dibenzyl hnker a,a -DiOxyXylyl diether, -0CH2C6H4CH20-, is not limited by restriction of the succinoyl hnker (1) when bound via a hydroxyl or as an... [Pg.187]

FIGURE 3.18 Protection of carboxyl groups by esterification of amino acids (A) by acid-catalyzed reaction with alcohol. [Curtius 1888, Fisher 1906] with X = Cl for H-Xaa-OMe, X-Xaa-OEt, and H-Pro-OCH2Ph ... [Pg.83]

See other pages where Acid-catalyzed reactions group is mentioned: [Pg.114]    [Pg.228]    [Pg.193]    [Pg.383]    [Pg.316]    [Pg.182]    [Pg.96]    [Pg.104]    [Pg.457]    [Pg.785]    [Pg.274]    [Pg.847]    [Pg.870]    [Pg.340]    [Pg.275]    [Pg.182]    [Pg.415]    [Pg.69]    [Pg.232]    [Pg.106]    [Pg.126]    [Pg.27]    [Pg.49]    [Pg.43]    [Pg.28]    [Pg.675]    [Pg.83]    [Pg.84]    [Pg.184]    [Pg.85]   
See also in sourсe #XX -- [ Pg.742 , Pg.744 ]



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