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Steric hindrance functional groups

The polyaddition reaction is influenced by the structure and functionality of the monomers, including the location of substituents in proximity to the reactive isocyanate group (steric hindrance) and the nature of the hydroxy] group (primary or secondary). Impurities also influence the reactivity of tlie system. [Pg.1653]

The polyaddition reaction is influenced by the structure and functionality of the monomers, including the location of substituents in proximity to the reactive isocyanate group (steric hindrance) and the nature of the hydroxyl group (primary or secondary). Impurities also influence the reactivity of the system for example, acid impurities in PMDI require partial neutralization or larger amounts of the basic catalysts. The acidity in PMDI can be reduced by heat or epoxy treatment, which is best conducted in the plant. Addition of small amounts of carboxylic acid chlorides lowers the reactivity of PMDI or stabilizes isocyanate terminated prepolymers. [Pg.342]

In the formate esters, the free energy difference decreases from esters to thioesters and amides for the methyl and tert-butyl groups, and E-methyl formate is only observed in very small amounts (<0.3%) at low temperature (190 K), as shown by 13C NMR spectroscopy [3], The energy is significantly lower for the bulky tert-butyl moiety relative to the methyl group and this seems to be a function of steric hindrance since ethyl formate and iso-propyl formate have intermediary values [4,5]. In the tert-butyl formate, a strong electronic repulsion accounts for the relatively high proportion of E isomer (10%). [Pg.144]

Figure 4.2. Rotational-energy barriers as a function of substitution. Tbe small barrier ( 2kcal) in ethane (a) is lowered even further ( O.Skcal) if three bonds are tied back by replacing three hydrogen atoms of a methyl group by a triple-bonded carbon, as in methylacetylene (b). The barrier is raised 4.2 kcal) when methyl groups replace the smaller hydrogen atoms, as in neopentane (c). Dipole forces raise the barrier further ( 15 kcal) in methylsuccinic acid (d) (cf. Figure 4.3). Steric hindrance is responsible for the high barrier (> 15 kcal) in the diphenyl derivative (e). (After... Figure 4.2. Rotational-energy barriers as a function of substitution. Tbe small barrier ( 2kcal) in ethane (a) is lowered even further ( O.Skcal) if three bonds are tied back by replacing three hydrogen atoms of a methyl group by a triple-bonded carbon, as in methylacetylene (b). The barrier is raised 4.2 kcal) when methyl groups replace the smaller hydrogen atoms, as in neopentane (c). Dipole forces raise the barrier further ( 15 kcal) in methylsuccinic acid (d) (cf. Figure 4.3). Steric hindrance is responsible for the high barrier (> 15 kcal) in the diphenyl derivative (e). (After...
A major improvement regarding epoxidation of terminal olefins was achieved upon exchanging pyridine for its less basic analogue 3-cyanopyridine (p Krl pyridine = 5.4 pKa 3-cyanopyridine = 1.9) [105]. This improvement turned out to be general for a number of different terminal olefins, irrespective of the existence of steric hindrance at the a-position of the olefin or the presence of other functional groups in the substrate (Scheme 6.13 and Table 6.9). [Pg.213]

Schemes are available, however, that start from the free carboxylic acid, plus an activator . Dicyclohexylcarbodiimide, DCC, has been extensively employed as a promoter in esterification reactions, and in protein chemistry for peptide bond formation [187]. Although the reagent is toxic, and a stoichiometric concentration or more is necessary, this procedure is very useful, especially when a new derivative is targeted. The reaction usually proceeds at room temperature, is not subject to steric hindrance, and the conditions are mild, so that several types of functional groups can be employed, including acid-sensitive unsaturated acyl groups. In combination with 4-pyrrolidinonepyridine, this reagent has been employed for the preparation of long-chain fatty esters of cellulose from carboxylic acids, as depicted in Fig. 5 [166,185,188] ... Schemes are available, however, that start from the free carboxylic acid, plus an activator . Dicyclohexylcarbodiimide, DCC, has been extensively employed as a promoter in esterification reactions, and in protein chemistry for peptide bond formation [187]. Although the reagent is toxic, and a stoichiometric concentration or more is necessary, this procedure is very useful, especially when a new derivative is targeted. The reaction usually proceeds at room temperature, is not subject to steric hindrance, and the conditions are mild, so that several types of functional groups can be employed, including acid-sensitive unsaturated acyl groups. In combination with 4-pyrrolidinonepyridine, this reagent has been employed for the preparation of long-chain fatty esters of cellulose from carboxylic acids, as depicted in Fig. 5 [166,185,188] ...
How do these NRRIs interact with their final target, the HCV RNA replicase They are phosphorylated to their 5 -triphosphate form, and then inhibit the HCV replicase. As they possess a 3 -hydroxyl function, they may not be considered as obligate chain terminators, but they may act as virtual chain terminators, viz. by steric hindrance exerted by the neighboring 2 -C-methyl and/or 4 -C-azido groups. Similar to their NRTI and NNRTI counterparts in the case of HIV reverse transcriptase, the NRRIs (2 -C-methylnucleosides) interact, upon their phosphorylation to the corresponding 5 -triphosphates, with a region of the HCV RNA replicase (or NS5B RNA-dependent RNA polymerase) that is clearly distinct from the site(s) of interaction of the NNRRIs (Tomei et al. 2005). [Pg.77]

In the case of 2-(2-hydroxyethyl)piperidine it is not necessary to protect the NH group because of steric hindrance at this position. The imino function within the pyridinoindole is not nucleophilic enough to react with CDI. [Pg.53]

As an example, bulk modification by the organic reaction of unsaturated PHA with sodium permanganate resulted in the incorporation of dihydroxyl or carboxyl functional groups [106]. Due to the steric hindrance of the isotactic pendant chains, complete conversion could not be obtained. However, the solubility of the modified polymers was altered in such a way that they were now completely soluble in acetone/water and water/bicarbonate mixtures, respectively [106]. Solubility can play an important role in certain applications, for instance in hydrogels. Considering the biosynthetic pathways, the dihydroxyl or carboxyl functional groups are very difficult to incorporate by microbial synthesis and therefore organic chemistry actually has an added value to biochemistry. [Pg.271]

An increase in the size of the carbocycle and steric hindrance of the base leads to a decrease in the contribution of the target enoxime in the reaction products. Hence, in each particular case it is necessary to perform special experiments to elucidate whether the scheme is applicable for the synthesis of conjugated enoximes containing a remote functional group and to find optimal conditions. [Pg.717]

See other pages where Steric hindrance functional groups is mentioned: [Pg.49]    [Pg.49]    [Pg.343]    [Pg.343]    [Pg.201]    [Pg.158]    [Pg.374]    [Pg.374]    [Pg.763]    [Pg.314]    [Pg.337]    [Pg.386]    [Pg.16]    [Pg.184]    [Pg.120]    [Pg.224]    [Pg.67]    [Pg.23]    [Pg.53]    [Pg.54]    [Pg.300]    [Pg.873]    [Pg.178]    [Pg.539]    [Pg.172]    [Pg.26]    [Pg.27]    [Pg.258]    [Pg.198]    [Pg.81]    [Pg.157]    [Pg.187]    [Pg.27]    [Pg.40]    [Pg.201]    [Pg.300]    [Pg.180]    [Pg.177]    [Pg.123]    [Pg.30]    [Pg.490]    [Pg.174]   
See also in sourсe #XX -- [ Pg.329 ]



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Hindrance, sterical

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