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Sulfonation 5-position

DNQ-sulfonate positive-resist formulations. However, as the demands on these formulations increased over time due to the ever-continuous march to ever-smaller geometries, requiring new image transfer steps such as ion implantation and plasma etching, new improved hinder resins were developed. [Pg.304]

FIGURE 11.5 (a) Different sulfonated position on the sulfonated polyphenylsulfone (b) the weight losses of... [Pg.311]

One approach is to increase the acidity and the stability of acidic function by moving the acid function from the ortho-to-ether position to the ortho-position of a strongly electron-withdrawing units i.e. ortho-to-sulfone position connecting the phenyl rings in the case of poly ether sulfone (UDEL). [Pg.83]

The ionic function can be added by (i) electrophilic substitution in ortho-to-ether position on arylene ether segment due to its electron-donating nature or by (ii) aromatic nucleophilic substitution in ortho-to-sulfone position. Due to the electron withdrawing nature of sulfonyl link present in arylene sulfone segment, the acidic character of hydrogen atom present ortho-to-sulfone link is quite high and hence, activated for nucleophilic substitution using lithiation chemistry. [Pg.86]

Ionic Function Attached Directly to Ortho-to-Sulfone Position of the Polymer... [Pg.89]

Kerres et al. [38] reported that the sulfonation close to electron-donating substituents (i.e. ortho-to-ether position) of the main aromatic polymer chain is normally more easily activated for hydrolytic desulfonation in acidic media compared to sulfonation close to electron-withdrawing substituents (i.e. ortho-to-sulfone position). An electrophilic route does not allow acidic ionic groups to be located on the ortho-to-sulfone position in the arylene sulfone segment where it should be, at least slightly, more dissociated than an acidic ionic function located at the ortho-to-ether position in the arylene ether segment. [Pg.89]

The sulfonation at ortho-to-sulfone position involves three successive steps, metalation-sulfination-oxidation as rej>orted by Kerres et al. [38] (Scheme 4.4). [Pg.89]

Scheme 4.4 Sulfonation and phosphonation of polysulfone in ortho-to-sulfone position. Scheme 4.4 Sulfonation and phosphonation of polysulfone in ortho-to-sulfone position.
Lafitte et al. [45] reported polysulfone ionomers functionalized with benzoyl(difluoromethylenephosphonic acid) side chain (bfp-PSU) as an alternative to sulfonic acid based PSU ionomers shown in Scheme 4.8(a) and Table 4.2. The degree of phosphonation (DP) was achieved up to 53% and this membrane took higher amount of water (6%) tmder immersed state at room temperature compared to membrane with phosphonic acid directly attached to main-chain at ortho-to-sulfone position taking 2% water as discussed before. The probable reason is the increased acidity of the phosphonic acid unit. The thermal stability was found to be inferior to sulfonated derivatives due to the presence of aryl -CF2-P linkage [45]. [Pg.96]

Alkyl halides and sulfonates are the most frequently used alkylating acceptor synthons. The carbonyl group is used as the classical a -synthon. O-Silylated hemithioacetals (T.H. Chan, 1976) and fomic acid orthoesters are examples for less common a -synthons. In most synthetic reactions carbon atoms with a partial positive charge (= positively polarized carbon) are involved. More reactive, "free carbocations as occurring in Friedel-Crafts type alkylations and acylations are of comparably limited synthetic value, because they tend to react non-selectively. [Pg.15]

Various terminal allylic compounds are converted into l-alkenes at room temperature[362]. Regioselective hydrogenolysis with formate is used for the formation of an exo-methylene group from cyclic allylic compounds by the formal anti thermodynamic isomerization of internal double bonds to the exocyclic position[380]. Selective conversion of myrtenyl formate (579) into /9-pinene is an example. The allylic sulfone 580 and the allylic nitro compound... [Pg.368]

In fuming sulfuric acid (20% oleum) 2 aminothiazole (16. 27. 375. 389) and 2-amino-4-methylthiazole (374. 390) are sulfonated in the 5-position. When this position is substituted as in 2-amino-5-methyl-thiazole (27, 391) very small amounts of 4-sulfonation occur. [Pg.75]

The 5-position is the preferred site for sulfonation (58. 392). This position is more reactive than any of the pyridine ring in. V-[pyridyl-(2)]-thiazolyl-(2)-amine (178) (132, 382, 383). [Pg.75]

Sulfonation by oleum occurs as expected on C-5 (598). The same position is reactive toward bromination, thiocyanation, and nitration... [Pg.113]

When unsubstituted, C-5 reacts with electrophilic reagents. Thus phosphorus pentachloride chlorinates the ring (36, 235). A hydroxy group in the 2-position activates the ring towards this reaction. 4-Methylthiazole does not react with bromine in chloroform (201, 236), whereas under the same conditions the 2-hydroxy analog reacts (55. 237-239. 557). Activation of C-5 works also for sulfonation (201. 236), nitration (201. 236. 237), Friede 1-Crafts reactions (201, 236, 237, 240-242), and acylation (243). However, iodination fails (201. 236). and the Gatterman or Reimer-Tieman reactions yield only small amounts of 4-methyl-5-carboxy-A-4-thiazoline-2-one. Recent kinetic investigations show that 2-thiazolones are nitrated via a free base mechanism. A 2-oxo substituent increases the rate of nitration at the 5-position by a factor of 9 log... [Pg.402]

When the 5-position is occupied by a methyl group, sulfonation takes place at C-4 (247). [Pg.403]

Direct sulfonation of thiazole, as well as of 2-substituted thiazoles, leads mostly to substitution m the 5-position (330-332). 4-Thiazole sulfonic acid has been prepared through direct sulfonation of 2.5-dibromothiazole with subsequent Rane% Ni reduction (330). Sulfonation of 2.5-dimethyl- and 2-piperidyl-5-methylthiazoles affords the corresponding 4-sulfonic acids as barium salts (247). The 2-hydroxy group facilitates the sulfonation (201. 236). When the 4- and 5-positions are occupied direct sulfonation can occur in the 2-position. 5-hydroxyethyl-4-methyl-2-thiazole sulfonic acid has been prepared in this manner (7). [Pg.413]

As in most electrophilic reactions, the abiUty to stabilize the positive charge generated by the initial addition strongly affects the relative rates. MX reacts faster than OX and PX because both methyl groups work in conjunction to stabilize the charge on the next-but-one carbon. Sulfonation was, at one time, used to separate MX from the other Cg aromatic isomers. MX reacts most rapidly to form the sulfonic acid which remains in the aqueous phase. The sulfonation reaction is reversible, and MX can be regenerated. [Pg.414]

Substitution Reactions on Side Chains. Because the benzyl carbon is the most reactive site on the propanoid side chain, many substitution reactions occur at this position. Typically, substitution reactions occur by attack of a nucleophilic reagent on a benzyl carbon present in the form of a carbonium ion or a methine group in a quinonemethide stmeture. In a reversal of the ether cleavage reactions described, benzyl alcohols and ethers may be transformed to alkyl or aryl ethers by acid-catalyzed etherifications or transetherifications with alcohol or phenol. The conversion of a benzyl alcohol or ether to a sulfonic acid group is among the most important side chain modification reactions because it is essential to the solubilization of lignin in the sulfite pulping process (17). [Pg.139]

Phthalocyanine sulfonic acids, which can be used as direct cotton dyes (1), are obtained by heating the metal phthalocyanines in oleum. One to four sulfo groups can be introduced in the 4-position by varying concentration, temperature, and reaction time (103). Sulfonyl chlorides, which are important intermediates, can be prepared from chlorosulfonic acid and phthalocyanines (104). The positions of the sulfonyl chloride groups are the same as those of the sulfonic acids (103). Other derivatives, eg, chlormethylphthalocyanines (105—107), / /f-butyl (108—111), amino (112), ethers (109,110,113—116), thioethers (117,118), carboxyl acids (119—122), esters (123), cyanides (112,124—127), and nitrocompounds (126), can be synthesized. [Pg.505]

Sulfonation. Aniline reacts with sulfuric acid at high temperatures to form -aminoben2enesulfonic acid (sulfanilic acid [121 -57-3]). The initial product, aniline sulfate, rearranges to the ring-substituted sulfonic acid (40). If the para position is blocked, the (9-aminoben2enesulfonic acid derivative is isolated. Aminosulfonic acids of high purity have been prepared by sulfonating a mixture of the aromatic amine and sulfolane with sulfuric acid at 180-190°C (41). [Pg.231]

Anthraquinone can be sulfonated, nitrated, or halogenated. Sulfonation is of the greatest technical importance because the sulfonic acid group can be readily replaced by an amino or chloro group. Sulfonation with 20—25% oleum at a temperature of 130—135°C produces predominandy anthraquinone-2-sulfonic acid [84-48-0]. By the use of a stronger oleum, disulfonic acids are produced. The second sulfonic acid substituent never enters the same ring a mixture of 2,6- and 2,7-disulfonic acids is formed (Wayne-Armstrong rule). In order to sulfonate in the 1-, 1,5-, or 1,8-positions, mercury or one of its salts must be used as a catalyst. [Pg.421]


See other pages where Sulfonation 5-position is mentioned: [Pg.377]    [Pg.60]    [Pg.297]    [Pg.2269]    [Pg.56]    [Pg.311]    [Pg.171]    [Pg.312]    [Pg.207]    [Pg.415]    [Pg.100]    [Pg.570]    [Pg.572]    [Pg.591]    [Pg.118]    [Pg.119]    [Pg.125]    [Pg.46]    [Pg.67]    [Pg.241]    [Pg.81]    [Pg.482]    [Pg.483]    [Pg.461]    [Pg.463]    [Pg.310]    [Pg.465]   
See also in sourсe #XX -- [ Pg.402 ]




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Ortho-to-sulfone position

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