Nitramines reactions with

Several color reactions can be used to detect nitramines reaction with aromatic amines in acetic acid (71), reaction with ferrous sulfate in sulfuric acid (72,73), diazotization with nitrous acid in 50% acetic acid, and coupling with a suitable component (74) (for aromatic nitramines) ... 

Oxidizers. The characteristics of the oxidizer affect the baUistic and mechanical properties of a composite propellant as well as the processibihty. Oxidizers are selected to provide the best combination of available oxygen, high density, low heat of formation, and maximum gas volume in reaction with binders. Increases in oxidizer content increase the density, the adiabatic flame temperature, and the specific impulse of a propellant up to a maximum. The most commonly used inorganic oxidizer in both composite and nitroceUulose-based rocket propellant is ammonium perchlorate. The primary combustion products of an ammonium perchlorate propellant and a polymeric binder containing C, H, and O are CO2, H2, O2, and HCl. Ammonium nitrate has been used in slow burning propellants, and where a smokeless exhaust is requited. Nitramines such as RDX and HMX have also been used where maximum energy is essential. 

The formation of chloramine as an intermediate, followed by reaction with nitric acid to produce the corresponding nitramine and HOC1, may explain the catalytic action of HC1 in the nitration of amines... 

More recently, Polish chemists have reported a synthesis of both aryl and aliphatic secondary nitramines by treating amine substrates with ethyl magnesium bromide followed by reaction with n-butyl nitrate (Equation 5.8). This method, which uses nonpolar solvents like hexane or benzene, has been used to synthesize aliphatic secondary nitramines, and At-nitro-A-methylanilines which otherwise undergo facile Bamberger rearrangement in the presence of acid. The direct nitration of At-unsubstituted arylamines usually requires the presence of an electron-withdrawing group. Reactions are retarded and yields are low for sterically hindered amines. 

The anions of primary nitramines, like other nucleophiles, can undergo Michael 1,4-addition reactions with a range of a,-unsaturated substrates to form secondary nitramines of varying molecular complexity (Equation 5.18). Kissinger and Schwartz prepared a number of secondary nitramines from the condensation of primary nitramines with a,/3-unsaturated ketones, esters, amides and cyanides. In a standard experiment a solution of the primary nitramine and... 

Primary nitramines react with amines in the presence of an aldehyde to form 1,3-amino-nitramines in a reaction analogous to the Mannich condensation. In these reactions the amine and aldehyde component combine to form an intermediate imine which is then attacked by the nitramine nucleophile. 

The alkylation of primary nitramines with alkyl halides is of little preparative value for the synthesis of secondary nitramines. Such reactions often result in a mixture of N- and 0-alkylated products. The product distribution appears to be very dependent on the nature of the cation of the nitramine used, with silver salts ° favouring 0-alkylation and alkali metal salts usually giving A-alkylation as the predominant product. However, this is not always the case. 

However, the yield of DPT from such reactions is often poor (15-25 %). DPT has also been synthesized from the reaction of hexamine dinitrate with acetic anhydride or cold 90 % aqueous sulphuric acid. Both methods under optimum conditions give yields of DPT of approximately 31 The reaction of nitramine (NH2NO2) with aqueous formaldehyde, followed by neutralization of the reaction mixture with ammonia to pH 5.5-6.5, gives DPT in 73 % yield based on the nitramine starting material. This last reaction presumably involves the formation of dimethylolnitramine as an intermediate (Section 5.15.4.2). 

The above observations allow the selective formation of RDX, HMX or the two linear nitramines (247) and (248) by choosing the right reaction conditions. For the synthesis of the linear nitramine (247), with its three amino nitrogens, we would need high reaction acidity, but in the absence of ammonium nitrate. These conditions are achieved by adding a solution of hexamine in acetic acid to a solution of nitric acid in acetic anhydride and this leads to the isolation of (247) in 51 % yield. Bachmann and co-workers also noted that (247) was formed if the hexamine nitrolysis reaction was conducted at 0 °C even in the presence of ammonium nitrate. This result is because ammonium nitrate is essentially insoluble in the nitrolysis mixture at this temperature and, hence, the reaction is essentially between the hexamine and nitric acid-acetic anhydride. If we desire to form linear nitramine (248) the absence of ammonium nitrate should be coupled with low acidity. These conditions are satisfied by the simultaneous addition of a solution of hexamine in acetic acid and a solution of nitric acid in acetic anhydride, into a reactor vessel containing acetic acid. 

Nitration of the amine (139) with mixed acid yields the energetic nitramine (140). The same reaction with sodium nitrite in sulfuric acid, or with nitrosyl fluoride in methylene chloride, yields the nitrosamine (141), which is also an energetic high explosive. ... 

The nitration of nitramine (153) with nitronium tetrafluoroborate, followed by neutralization of the resulting dinitraminic acid with ammonia, also generates ammonium dinitramide (152). Neutralization of this reaction with alkylamines, instead of ammonia, yields the corresponding alkylammonium salts of dinitramide. The nitration of ammonia with dinitrogen pentoxide (15 %) or nitronium salts like the tetrafluoroborate (25 %) yield ammonium dinitramide (152) through the initial formation of nitramine. 

Alkyl lV,lV-dinitramines (154) have been prepared from the reaction of the tetraalkylam-monium salts (155) of primary nitramines with nitryl fluoride in acetonitrile at subambient temperature. The same reaction with the primary nitramine or its alkali metal salts yields the corresponding nitrate ester. Treatment of the ammonium, potassium, or lithium salts of primary nitramines (156) with a solution of nitronium tetrafluoroborate in acetonitrile at subambient temperature yield alkyl iV,iV-dinitramines. ° The same reactions in ether or ester solvents enables the free nitramine to be used. The nitrolysis of A-alkylnitramides (157) and N,N-diacylamines with nitronium tetrafluoroborate in acetonitrile, and the nitration of aliphatic isocyanates with nitronium tetrafluoroborate and nitric acid in acetonitrile, also yield alkyl A,A-dinitramines (154). 

Reaction with liquid ammonia at —33°C probably proceeds in a manner similar to that described by Davis and Blanchard it is believed that nitramine (decomposing into N20 and water) and urea (apparently from cyanic acid and ammonia) are formed. 

Reagents for amination, nitrosation and nitration of tertiary alkylamines are discussed in the appropriate reviews listed in Sections 6.1.3.1.4 and 6.I.3.I.5. Tertiary amines can be nitrosated with dealkylation by dinitrogen tetroxide for example, 1-methylpiperidine gave 1-nitrosopiperidine (80%). lliis reaction probably starts by one-electron oxidation of the amine, the aminium ion then undergoing dealkylation. Other oxidative d ylations and dealkylations include the formation of iV-nitrosodibenzylamine in high yield from the acid chloride (PhCH2)2NCOCl and sodium nitrite and the conversion of the amine (43) into the nitramine (44) with nitric acid. ... 

Primary nitramines react with foniiaidehyde to yield A -hydroxyniethyl compounds. Tlie reaction is reversible [24] ... 

An important goal of these new experiments is to develop a link between the physical properties and molecular structures of different nitramines and their combustive behavior. The motivation of the work on the condensed phase is to obtain a better understanding of the physical processes and reaction mechanisms that occur, so that the identity and rate of release of the pyrolysis products can be predicted, as a function of pressure and heating rate, based on the physical properties and molecular structure of the material. This information can then be used along with the gas-phase reaction models to correlate modifications of the nitramine ingredients with variations in die overall combustion. 

Organic esters of nitric acid give a color reaction with ferrous sulfate and cone, sulfuric acid [this reaction is also given by nitramines (30, 31)] or with phenoldisulfonic acid (32), and also with diphenylamine in sulfuric acid [see also nitramines (33, 34)]. 

The Liebermann reaction can also be used, as in the case of nitroso compounds. This reaction is also given by nitramines—compounds with the groupings... 

The anhydride of nitric acid, N20, reacts with 2-methyl aziridine to give the dinitrate (105). In the case of A/-substituted aziridines, the reaction stops at the stage of the nitramine nitrate prior to elimination of N2O (106). 

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