Amines and aromatic

The most versatile derivative from which the free base can be readily recovered is the picrate. This is very satisfactory for primary and secondary aliphatic amines and aromatic amines and is particularly so for heterocyclic bases. The amine, dissolv in water or alcohol, is treated with excess of a saturated solution of picric acid in water or alcohol, respectively, until separation of the picrate is complete. If separation does not occur, the solution is stirred vigorously and warmed for a few minutes, or diluted with a solvent in which the picrate is insoluble. Thus, a solution of the amine and picric acid in ethanol can be treated with petroleum ether to precipitate the picrate. Alternatively, the amine can be dissolved in alcohol and aqueous picric acid added. The picrate is filtered off, washed with water or ethanol and recrystallised from boiling water, ethanol, methanol, aqueous ethanol, methanol or chloroform. The solubility of picric acid in water and ethanol is 1.4 and 6.23 % respectively at 20°. 

With respect to aromatic substrates, the Vilsmeier formylation reaction works well with electron-rich derivatives like phenols, aromatic amines and aromatic heterocycles like furans, pyrroles and indoles. However various alkenes are also formylated under Vilsmeier conditions. For example the substituted hexatriene 6 is converted to the terminal hexatrienyl aldehyde 7 in 70% yield ... 

First reported by Fredenhagen in 1926 F3, F4), the graphite-alkali-metal compounds possess a relative simplicity with respect to other intercalation compounds. To the physicist, their uncomplicated structure and well defined stoichiometry permit reasonable band-structure calculations to be made S2,12) to the chemist, their identity as solid, "infinite radical-anions frequently allows their useful chemical substitution for such homogeneous, molecular-basis reductants as alkali metal-amines and aromatic radical anions N2, B5). 

Rao and Singh32 calculated relative solvation free energies for normal alkanes, tetra-alkylmethanes, amines and aromatic compounds using AMBER 3.1. Each system was solvated with 216 TIP3P water molecules. The atomic charges were uniformly scaled down by a factor of 0.87 to correct the overestimation of dipole moment by 6-31G basis set. During the perturbation runs, the periodic boundary conditions were applied only for solute-solvent and solvent-solvent interactions with a non-bonded interaction cutoff of 8.5 A. All solute-solute non-bonded interactions were included. Electrostatic decoupling was applied where electrostatic run was completed in 21 windows. Each window included 1 ps of equilibration and 1 ps of data... 

In the literature, there are numerous reports regarding the interactions between amines and both electron and proton acceptors132, but less attention has been devoted to interactions between amines and aromatic electron acceptors, in particular when the substrate/amine system is a reacting system, as in the case of nucleophilic aromatic substitution (SjvAr) reactions between amines and substrates activated by nitro or by other electron-withdrawing groups. 

Fig. 30 Biogenic amines and aromatic compounds characterized from saturniid caterpillars...

Phenylquinoxalines - Polyphenylquinoxalines (PPQ) prepared from the reaction of aromatic bi s (o-di amines) and aromatic bis (phenyl-ot-diketones) are high temperature thermoplastics. They are process-able with little or no volatile evolution at relatively high temperatures (> 316°C) and pressure (-1.38 MPa) by virtue of their thermoplasticity. Like other thermoplastics, the processability is governed primarily by the chemical structure, molecular weight and molecular weight distribution. 

Behaviour with halogenated solvents, bases, oxidizing acids, amines and aromatic oxygenated solvents can be limited. 

During the biosynthetic transformation, chorismate is the point of divergence for the biosynthesis of Phe, Tyr, Trp, and other amino acids containing aromatic groups. For example, the biosynthesis of Trp begins with the conversion of chorismate to anthranilate (Scheme 4(a)). A sequence of amination and aromatization reactions produces anthranilate, which is then condensed with phosphoribosylpyrophosphate. The intermediate is carried through a series of reactions to yield Trp (Scheme 4(b)). 

To carry out MCRs of aminoazoles with aldehydes and cyclic CH-acids, the methods of green chemistry were also applied. For example, treatments of 3-methylisoxazol-5-amine and aromatic aldehydes with 1,3-cyclohexanedione, dimedone, 1,3-indanedione, or titronic acid were proceeded in water under micro-wave irradiation at 120°C [100] (Scheme 31). As a result, clean, efficient, and convenient procedures for the generation of polycyclic-fused isoxazolo[5,4-b] pyridines 71 were developed. An interesting fact is that, in the case of 1,3-cyclohexanedione, dihydropyridine s were obtained while in aU other cases only hetero-aromatized derivatives were isolated. No reason for this experimental fact was discussed in the article. 

A very flexible method of preparing unsymmetrical azo compounds makes use of the condensation of C-nitroso compounds with amines. Thionylamines have also been condensed with substituted hydroxylamines to produce azo compounds not usually accessible by other means. Treatment of dialkylsulfuric diamides with sodium hypochlorite is one means of preparing aliphatic azo compounds. Aromatic amines and aromatic nitro compounds at high temperature produce azo compounds. 

This book reviews some of the results of investigations of chemical conversions of chloral and TNT to new aromatic di(poly)amines and aromatic tetracarboxylic acid dianhydrides useful for the preparation of new polyimides combining good thermal, mechanical and electrical properties with improved processability. 

Amines, reactions of, 1072, 1073 see also Aliphatic amines and Aromatic amines... 

Support-bound triazenes, which can be prepared from resin-bound secondary aliphatic amines and aromatic diazonium salts [455], undergo cleavage upon treatment with acids, leading to regeneration of the aromatic diazonium salts. In cross-linked polystyrene, these decompose to yield nitrogen and, preferentially, radical-derived products. If the acidolysis of polystyrene-bound triazenes is conducted in the presence of hydrogen-atom donors (e.g. THF), unsubstituted arenes can be obtained (Entries 8 and 9, Table 3.47). In the presence of alkenes or alkynes and Pd(OAc)2, the initially formed diazonium salts undergo Heck reaction to yield vinylated or alkynylated arenes (Entry 10, Table 3.47). Similarly, unsubstituted arenes can be obtained by oxida-... 

TNT forms charge-transfer, or 7r, complexes with polycyclic aromatic hydrocarbons, aromatic amines, and aromatic nitro compds a number of these are listed below in Table 2. The complexes with three amines (diphenylamine, diethyl-aniline, p-anisidine) have characteristic colors this forms the basis for a rapid and convenient thin-layer chromatographic analytical procedure (Ref 34) for the identification of very small amounts of TNT. (For a discussion of the many color reactions of TNT, and of composite expls containing it, see Vol 3, C405-L ff)... 

Secondary amines can be prepared from the primary amine and carbonyl compounds by way of the reduction of the derived Schiff bases, with or without the isolation of these intermediates. This procedure represents one aspect of the general method of reductive alkylation discussed in Section 5.16.3, p. 776. With aromatic primary amines and aromatic aldehydes the Schiff bases are usually readily isolable in the crystalline state and can then be subsequently subjected to a suitable reduction procedure, often by hydrogenation over a Raney nickel catalyst at moderate temperatures and pressures. A convenient procedure, which is illustrated in Expt 6.58, uses sodium borohydride in methanol, a reagent which owing to its selective reducing properties (Section 5.4.1, p. 519) does not affect other reducible functional groups (particularly the nitro group) which may be present in the Schiff base contrast the use of sodium borohydride in the presence of palladium-on-carbon, p. 894. 

The most popular test for the presence or absence of free amino groups is the Kaiser test.10 The test is simple and quick however it should be noted that some deprotected amino acids do not show the expected dark blue color typical of free primary amino groups (e.g., serine, asparagine, aspartic acid).11 Furthermore, for secondary amines such as proline, the resin will turn brown instead of blue. For secondary amines and aromatic amines, the chloranil test is recommended.12 In this volume, Albericio s research... 

Amides are less basic than amines, and aromatic amines are less basic than aliphatic amines. Therefore, the order is ... 

Analytical Properties (i-Cyclodextrin (cycloheptamylose) normal phase separation of positional isomers of substituted benzoic acids reverse phase separation of dansyl and napthyl amino acids, several aromatic drugs, steroids, alkaloids, metallocenes, binapthyl crown ethers, aromatics acids, aromatic amines, and aromatic sulfoxides this substrate has seven glucose units and has a relative molecular mass of 1135 the inside cavity has a diameter of 0.78 nm, and the substrate has a water solubility of 1.85 g/ml, although this can be increased by derivatization Reference 13-28... 

We have investigated a variety of clusters with ethers and amines as the Rydberg donor systems and polar solvents as the acceptors. The donors we have studied include dioxane (C4H802), azabicyclooctane (ABCO), diazabicyclooctane (DABCO), hexamethylenetetramine (HMT), and others (Moreno et al. 1992 Shang and Bernstein 1994 Shang et al. 1993a,b,c, 1994a,b,c). The acceptors include ethers, amines, and aromatics. 

Since amines are organic bases, water solutions show weakly basic properties. If the basicity of aliphatic amines and aromatic amines are compared to ammonia, aliphatic amines are stronger than ammonia, while aromatic amines are weaker. Amines characteristically react with acids to form ammonium salts the nonbonded electron pair on nitrogen bonds the hydrogen ion. 

The reaction of ethyl cyanothioacetate (492) with an amine and aromatic aldehydes affords diversely substituted 5-arylidene-2-iminothiazolidin-4-one derivatives (493 Scheme 272) (71NKZ867). Thiazolidinium salts (496) are formed by reaction of thiiranes (494) with dimethylchloromethylamine (495) in acetonitrile (Scheme 273) (70CB3058). 

Nitro-3-phenylisoxazole-5-carboxylates (290) act as heterocyclic 1-azadiene components in [4 + 2] cycloaddition reaction with some enamines affording bicyclo derivatives 295 probably via a stepwise ionic cycloaddition involving the Michael adducts 292 as primary intermediates. Further intramolecular attack by the isoxazole nitrogen on the immonium carbon followed by elimination of the amine and aromatization of dihydropyridine 293 afforded 294, which was transformed into pyridine 295 by simple reduction164 (equation 63). 

The same approach can be used for larger data sets and will be investigated further [30]. Important is that clusters must be identified and separate designs made within each cluster. In this example, primary amines and aromatic aldehydes were used and no apparent groupings were observed within these classes. 

A series of oxygenated pyrrole derivatives have been obtained in moderate yields in an approach involving sodium diethyl oxalacetate, amines, and aromatic aldehydes, as illustrated by the preparation of the product 531 (Equation 144) <2006T6018>. 

Intramolecular complex formation between tertiary amines and aromatic hydrocarbons is strongly affected by the hybridisation of the nitrogen. Van... 

The study of the production of excited states by the thermolysis of 1,2-dioxetanes is quite extensive (e.g. Nakamura and Goto, 1979a,b). It has been found that the addition of electron donors, e.g. amines and aromatic hydrocarbons (in the ground state), accelerate the decomposition. The process has... 

Photoinduced electron transfer between amines and aromatic hydrocarbons occurs to generate radical cations of amines and radical anions of aromatic hydrocarbons. Pac and Sakurai reported the photoaddition of N,N-dimethylaniline to anthracene via photoinduced electron transfer [60]. In benzene, the 4n + 4n) photocyclodimer of anthracene is produced as a sole isolable product, although an emission due to the exciplex formed from anthracene and JV,N-dimethylaniline is observed. In acetonitrile, the addition of dimethylaniline to anthracene occurs via their radical ions to give 9,10- dihydro-9-(4 -dimethylaminophenyl)anthracene as the major product. However, the photoamination on anthracene takes place even in benzene when iV-methylani-line is used as an electron donor. Sugimoto and his coworkers reported the intramolecular photoaddition of anilines to aromatic hydrocarbons to give cyclic amino compounds (Scheme 16) [61-63]. 

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