Alkylamines, primary

The small differences in basicity between fflumonia and alkylamines, and fflnong the various classes of alkylamines (primary, secondary, tertiary), come from a mix of effects. Replacing hydrogens of ammonia by alkyl groups affects both sides of the acid-base equilibrium in ways that largely cancel. 

We learned in the preceding section that different reactions are observed when the various classes of alkylamines—primary, secondary, and tertiary—react with nitrosating agents. Although no useful chemistr-y attends the nitrosation of tertiar y alkylamines, electrophilic aromatic substitution by nitrosyl cation ( n Q ) takes place with A,A-dialkyl-arylfflnines. 

Unlike primary alkylamines, primary arenamines react with nitrous acid at 0° to give diazonium ions that, in most cases, are stable enough to be isolated as crystalline BF4Q salts. Other salts can be isolated, but some of these, such as benzenediazonium chloride, in the solid state may decompose with explosive violence ... 

We learned in the preceding section that different reactions are observed when the various classes of alkylamines—primary, secondary, and tertiary—react with nitrosating... 

The various substituted hexahydrotriazines result from condensation of primary alkylamines, primary hydroxyalkylamines and primary alkoxyalkylamines. These donor substances differ from formalin in their lesser volatility, longer effect, anticorrosive effect and better skin tolerability. However, the differences in these properties are quite considerable within the three derivative groups. 

Amines are named m two mam ways m the lUPAC system either as alkylamines or as alkanamines When primary amines are named as alkylamines the ending amine IS added to the name of the alkyl group that bears the nitrogen When named as alkan amines the alkyl group is named as an alkane and the e ending replaced by amine... 

A method that achieves the same end result as that desired by alkylation of ammonia but which avoids the formation of secondary and tertiary amines as byproducts is the Gabriel synthesis Alkyl halides are converted to primary alkylamines without contam mation by secondary or tertiary amines The key reagent is the potassium salt of phthal imide prepared by the reaction... 

Figure 22 5 shows what happens when a typical primary alkylamine reacts with nitrous acid Because nitrogen free products result from the formation and decomposition of diazonium ions these reactions are often referred to as deamination reactions Alkyl... 

Ammonia can act as a nucleophile toward primary and some secondary alkyl halides to give primary alkylamines Yields tend to be modest because the primary amine IS itself a nucleophile and undergoes alkylation Alkylation of ammonia can lead to a mixture containing a primary amine a secondary amine a tertiary amine and a quaternary ammonium salt... 

Alkylation of phthalimide The Gabriel synthesis (Section 22 8) The potassium salt of phthalimide reacts with alkyl hal ides to give N alkylphthalimide deriva fives Hydrolysis or hydrazinolysis of this derivative yields a primary alkylamine... 

Alkyl azides prepared by nucleophilic substitution by azide ion in primary or secondary alkyl halides are reduced to primary alkylamines by lithium aluminum hydride or by catalytic hydrogenation... 

Gabriel synthesis (Section 22 8) Method for the synthesis of primary alkylamines in which a key step is the formation of a carbon-nitrogen bond by alkylation of the potassium salt of phthalimide... 

Primary amine (Section 22 1) An amine with a single alkyl or aryl substituent and two hydrogens an amine of the type RNH2 (pnmary alkylamine) or ArNH2 (primary aryl amine)... 

Lithium amides of primary / fZ-alkylamines yield N-(/ f2 -alkyl)-0-(/ f2 -butyl)hydroxylamines, whereas lithium amides of primary alkylamines yield A/-alkylbenzamides and LiOO—due to nucleophilic attack on the carbonyl group (245). 

Substituted Amides. Monosubstituted and disubstituted amides can be synthesized with or without solvents from fatty acids and aLkylamines. Fatty acids, their esters, and acid halides can be converted to substituted amides by reaction with primary or secondary aLkylamines, arylamines, polyamines, or hydroxyaLkylamines (30). Di- -butylamine reacts with oleic acid (2 1 mole ratio) at 200—230°C and 1380 kPa (200 psi) to produce di-A/-butyloleamide. Entrained water with excess -butylamine is separated for recycling later (31). 

Reductive amination of cyclohexanone using primary and secondary aHphatic amines provides A/-alkylated cyclohexylamines. Dehydration to imine for the primary amines, to endocycHc enamine for the secondary amines is usually performed in situ prior to hydrogenation in batch processing. Alternatively, reduction of the /V-a1ky1ani1ines may be performed, as for /V,/V-dimethy1 cyclohexyl amine from /V, /V- di m e th y1 a n i1 i n e [121 -69-7] (12,13). One-step routes from phenol and the alkylamine (14) have also been practiced. 

Amination. Amyl alcohols can react with ammonia or alkylamines to form primary, secondary, or tertiary-substituted amines. Eor example, 3-methyl-butylamine [107-85-7] is produced by reductive ammonolysis of 3-methyl-1-butanol over a Ni catalyst at 150°C (59). Some diisoamyl- and triisoamyl amines are also formed in this reaction. Good selectivities (88%) of neopentyl amine [5813-64-9] are similarly produced by reductive ammonolysis of neopentyl alcohol (60). 

Intramolecular alkylnitrene addition to an alkenic moiety situated S,e to the electron deficient center has been utilized for the preparation of bi- and tri-cyclic aziridines (Scheme 11) (68JA1650). Oxidation of the primary alkylamine can be effected cleanly with NCS, LTA or mercury(II) oxide. 

Relationships connecting stmcture and properties of primary alkylamines of normal stmcture C, -C gin chloroform and other solvents with their ability to extract Rh(III) and Ru(III) HCA from chloride solutions have been studied. The out-sphere mechanism of extraction and composition of extracted associates has been ascertained by UV-VIS-, IR-, and H-NMR spectroscopy, saturation method, and analysis of organic phase. Tertiary alkylamines i.e. tri-n-octylamine, tribenzylamine do not extract Ru(III) and Rh(III) HCA. The decrease of radical volume of tertiary alkylamines by changing of two alkyl radicals to methyl make it possible to diminish steric effects and to use tertiary alkylamines with different radicals such as dimethyl-n-dodecylamine which has not been used previously for the extraction of Rh(III), Ru(III) HCA with localized charge. 

FIGURE 22.5 The diazonium ion generated by treatment of a primary alkylamine with nitrous acid loses nitrogen to give a carbocation. The isolated products are derived from the carbocation and include, in this example, alkenes (by loss of a proton) and an alcohol (nucleophilic capture by water). 

Primary arylfflnines, like primary alkylamines, for-m diazonium ion salts on nitro-sation. Ar-yl diazonium ions are considerably more stable than their- alkyl counterparts. Whereas alkyl diazonium ions decompose under the conditions of their for-mation, aryl diazonium salts are stable enough to be stored in aqueous solution at 0-5°C for a reasonable time. Loss of nitrogen from an aryl diazonium ion generates an unstable aryl cation and is much slower than loss of nitrogen from an alkyl diazonium ion. 

Some substituents such as the acylamino group are readily decomposed by many nucleophiles to give a poorer leaving group (e.g., amino). Others, such as nitroamino and sulfonylamino, are less reactive when they are anionized by the nucleophile. 3-Nitroamino-pyridazine (117) and its 6-methyl derivative are readily aminated with benzylamine (130°, short time ). 4,6-Dimethyl- and 6-methyl-2-nitroaminopyrimidine undergo 2-substitution on warming a few minutes with hydroxylamine, hydrazine, primary or secondary alkylamines, or anilines. 

It was clearly shown by NMR spectroscopy that the addition of ammonia or primary or secondary alkylamines at position 5 of the 1,2,4-triazine 4-oxides to give the adducts 89 is a kinetically controlled process, while addition at position 3 to form the ring-opening products 85 is a thermodynamically controlled process. 

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