Primary amines, 31 Table formation

The ET-sensitized photoamination of 1,1-diarylethylenes with ammonia and most primary amines yields the anti-Markovnikov adducts. Photoamination of unsymmetrically substituted stil-benes yields mixtures of regioisomers 15 and 16. Modest re-gioselectivity is observed for p-methyl or p-chloro substituents however, highly selective formation of adduct 15 is observed for the p-methoxy substituent (Table 5). Selective formation of 15 was attributed to the effect of the methoxy substituent on the charge distribution in the stilbene cation radical. This re-gioselectivity has been exploited in the synthesis of intermediates in the preparation of isoquinolines and other alkaloids." Photoamination of 1-phenyl-3,4-dihydronaphthalene yields a mixture of syn and anti adducts 17 and 18 (Scheme 5)." Use of bulky primary amines favors formation of the syn adduct (Table 5), presumably as a consequence of selective anti protonation of the intermediate carbanion. 

While the early part of the acid-catalyzed path to form an imine (i.e., production of a protonated hemiaminal) appears the same for secondary amines (Table 9.4, 2b) and primary amines (Table 9.4,2a), the absence of a proton on nitrogen denies that intermediate the ability to lose water as shown in Scheme 9.65. Therefore, if there is a proton on the adjacent carbon, water is lost with the formation of a nitrogenbearing, carbon-carbon double bond species called an enamine (Scheme 9.66). Although it wiU be discussed later in this chapter when addition to the carbon a alpha) to the carbonyl (C=0) is separately considered it is worthwhile noting here... 

Rosenblatt etal have examined the effect of structure and isotopic substitution upon the permanganate oxidation of some alky famines (Table 4). The isotope effect of 1.84 is considered to be sufficiently low to be compatible with aminium radical-cation formation, and it is felt that, while C-H cleavage is significant for oxidation of primary amines, the dominant mode of oxidation of tertiary amines is electron-transfer, e.g. 

Although the extraction of primary amines from a basic medium with chloroform is an inadvisable procedure, on account of the formation of trace amounts of the pungent isonitriles, the specific synthesis of isonitriles by the two-phase reaction of primary amines with chloroform is unreliable. However, the application of the phase-transfer technique [e.g. 1 -5] for the controlled release of dichlorocarbene facilitates the synthesis of isonitriles in relatively high yields (Table 7.12). 

Protected primary allylic amines were generated from allylic carbonates and ammonia equivalents. Iridium-catalyzed allylic substitution has now been reported with sulfonamides [90, 91], imides [89, 91-93], and trifluoroacetamide [89] to form branched, protected, primary allylic amines (Table 5). When tested, yields and selectivities were highest from reactions catalyzed by complexes derived from L2. Reactions of potassium trifluoroacetamide and lithium di-tert-butyhminodi-carboxylate were conducted with catalysts derived from the simplified ligand L7. Reactions of nosylamide and trifluoroacetamide form singly-protected amine products. The other ammonia equivalents lead to the formation of doubly protected allylic amine products, but one protecting group can be removed selectively, except when the product is derived from phthalimide. 

Carbon-Nitrogen Bond Formation Based on Hydrogen Transfer 129 Table 5.11 N-Heterocyclization of primary amines with a variety of diols by [Cp lrCl2]2 (1) ... 

Fluorescence of PDC is also quenched by amines. The ordering of reactivity is tertiary > secondary > primary, which follows inversely the ionization potential (Table 9.13). The results are explained as indicating that PDC undergoes photoreduction by amines, thereby forming triplet charge-transfer intermediates as the primary step in quenching. Therefore, the mechanism of the PDC reaction is not the same as the proposed mode of reaction of PDC, which involves direct formation of an yhde intermediate by electrophilic attack on the lone-pair electrons of the amine (Table 9.13). ... 

Naphthalene- and anthracene-derived phenols did, however, almost uniformly precipitate (Table VI). In natural materials (not grapes or wines) which contain them they would be included in the formaldehyde precipitable group. Several primary amines capable of SchifFs base formation reacted with formaldehyde to lose their F-C oxidizability, but only the resorcinol analog, 3-aminophenol, precipitated (Table VIII). Sulfite also reacted but did not precipitate with formaldehyde, and the F-C oxidizability was suppressed (Table IX). The resorcinol derivative, 2,4-dimethoxycinnamic acid, formed a precipitate with formaldehyde, but it did not react appreciably in the F-C assay. 

Oximes generally require strong reducing agents to undergo complete conversion to primary amines (Entry 8, Table 10.8) the use of weaker reducing reagents, such as borane, leads mainly to the formation of hydroxylamines (see Section 10.3). 

The results show that a number of ruthenium carbonyl complexes are effective for the catalytic carbonylation of secondary cyclic amines at mild conditions. Exclusive formation of N-formylamines occurs, and no isocyanates or coupling products such as ureas or oxamides have been detected. Noncyclic secondary and primary amines and pyridine (a tertiary amine) are not effectively carbonylated. There appears to be a general increase in the reactivity of the amines with increasing basicity (20) pyrrolidine (pKa at 25°C = 11.27 > piperidine (11.12) > hexa-methyleneimine (11.07) > morpholine (8.39). Brackman (13) has stressed the importance of high basicity and the stereochemistry of the amines showing high reactivity in copper-catalyzed systems. The latter factor manifests itself in the reluctance of the amines to occupy more than two coordination sites on the cupric ion. In some of the hydridocar-bonyl systems, low activity must also result in part from the low catalyst solubility (Table I). 

Aliphatic nitro compounds are reduced to various products, in all the published examples, only C-F bonds at a-positions are reduced, while the nitro group can be reduced in two steps. Catalytic hydrogenation of primary nitro compounds over palladium transforms them to the corresponding isonitroso compounds, i. e. oximes, while secondary nitro groups are converted into amines (Table 4). The reduction with Raney nickel alloy converts all types of nitro compounds into the corresponding amines, e. g. formation of 14.136... 

The fluorescence of 3-t (113-117) and 3-7 (118) is quenched by secondary and tertiary amines. Rate constants for quenching of It by tertiary amines increase with decreasing amine ionization or oxidation potential (Table 11), as expected for the formation of a charge-transfer stabilized exciplex in which the amine serves as the electron donor. Electron transfer quenching in nonpolar solvent is calculated to be exothermic for amines with E 2 < 1 34 V. Thus, it is not surprising that secondary and tertiary amines quench 3-t with rate constants which approach or even exceed the rate of diffusion. The inefficient quenching of It and 3-7 by primary amines is consistent with their higher oxidation potentials. 

Less attention has been paid to the use of amines as nucleophiles in the telomerization reaction. A single report from Nolan and co-workers [233] has shown that well-defined cationic palladium complexes are efficient catalysts in the telomerization of butadiene with amines under mild conditions (Table 10). In the case of primary amines, the concentration of the reactants and their steric hinderance dictates the formation of a mono- or double-alkylated product. 

In the reductive alkylation of ammonia with cyclohexanone, Skita and Keil found that, although cyclohexylamine was obtained in 50% yield over a nickel catalyst, over colloidal platinum dicyclohexylamine was produced as the predominant product even in the presence of an excess molar equivalent of ammonia. Steele and Rylander compared the selectivity to primary amine, secondary amine, and alcohol in the reductive alkylation of ammonia with 2- and 4-methylcyclohexanones over 5% Pd-, 5% Rh-, and 5% Ru-on-carbon as catalysts.18 As seen from the results shown in Table 6.2, the formation of secondary amine is greatly depressed by the methyl group at the 2 position. Thus over Pd-C the secondary amine was formed predominantly with cyclohexanone and 4-methylcyclohexanone while the primary amine was produced in 96% selectivity with 2-methylcyclohexanone. Over Ru-C the alcohol was formed quantitatively with 4-methylcyclohexanone without the formation of any amines, whereas with 2-methylcyclohexanone the alcohol was formed only to an extent of 57%, accompanied by the formation of 4 and 39% of the secondary and primary amines, respectively. These results indicate that secondary amine formation is affected by the steric hindrance of the methyl group to a much greater extents than is the formation of the primary amine or the alcohol. The results with Ru-C and Rh-C also indicate... 

Ketones and secondary amines furnish enamines in the presence of TiCl4 [580,581]. The preparation of a functionalized enamine shown in Eq. (251), in which the acetal moiety is retained in the product, illustrates the applicability of this reaction [582]. Enamines prepared by this method are summarized in Table 24. Application to an intramolecular reaction is also found in Table 24. If formation of the enamine is thermodynamically preferred to formation of the isomeric imine, the former becomes the product even in the reaction of a ketone, a primary amine, and TiCl4, as shown in Eq. (252) [583], in which the resulting enamine was, after acetylation, isolated as the enamide. 

The determination of the volume profile indicates a significant electrostriction related to the formation of zwitterions generating activation volumes oscillating between —40 to —55 cm mol [37]. At ambient pressure the reaction is usually facile when using unsubstituted primary amines and unhindered acrylates. It does not require catalysis at all on account of the basicity of amines. However, its sensitivity to steric hindrance is so high that only a combination of high pressure and lanthanide catalysis is an efficient way to synthesize congested yS-aminoesters (Table 10.9) [38]. 

NBR-PP blends can be improved through copolymer formation between the two immiscible polymers concurrent with vulcanization. In the first example in Table 5.36, block copolymer resulted from reaction of amine-terminated NBR with anhydride-terminated PP. The latter was prepared through functionalization of PP with MA in the presence of radical initiator (see Section 5.8.8). In the second example, a block copolymer may have resulted from reaction of acid-terminated NBR with a primary amine-terminated PP. The latter was prepared in a prior reaction between maleic anhydride-terminated PP and tri-ethylenetetramine. It is also possible that the block copolymer may be linked through iono-meric association resulting from protonation of PP-amine with NBR acid (see Section 5.12.4). 

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