nitrogen-dioxide and cyclonite

nitrogen-dioxide has been researched along with cyclonite* in 2 studies

Other Studies

2 other study(ies) available for nitrogen-dioxide and cyclonite

Article	Year
Aminoxyl (nitroxyl) radicals in the early decomposition of the nitramine RDX. The journal of physical chemistry. A, 2013, Mar-14, Volume: 117, Issue:10 The explosive nitramine RDX (1,3,5-trinitrohexahydro-s-triazine) is thought to decompose largely by homolytic N-N bond cleavage, among other possible initiation reactions. Density-functional theory (DFT) calculations indicate that the resulting secondary aminyl (R2N·) radical can abstract an oxygen atom from NO2 or from a neighboring nitramine molecule, producing an aminoxyl (R2NO·) radical. Persistent aminoxyl radicals have been detected in electron-spin resonance (ESR) experiments and are consistent with autocatalytic "red oils" reported in the experimental literature. When the O-atom donor is a nitramine, a nitrosamine is formed along with the aminoxyl radical. Reactions of aminoxyl radicals can lead readily to the "oxy-s-triazine" product (as the s-triazine N-oxide) observed mass-spectrometrically by Behrens and co-workers. In addition to forming aminoxyl radicals, the initial aminyl radical can catalyze loss of HONO from RDX. Topics: Electron Spin Resonance Spectroscopy; Explosive Agents; Kinetics; Nitrogen Dioxide; Nitrogen Oxides; Nitrosamines; Oxygen; Quantum Theory; Thermodynamics; Triazines	2013
Spin trapping of nitrogen dioxide radical from photolytic decomposition of nitramines. Free radical biology & medicine, 1993, Volume: 15, Issue:3 The photochemical (lambda < 400 nm) decomposition of some monocyclic and polycyclic nitramines produces .NO2, which can be detected in the respective nitramine crystals at 77 K by EPR (electron paramagnetic resonance). In solutions of perdeutero-dimethylsulfoxide (DMSO-d6) the .NO2 produced by photolytic decomposition of dissolved nitramines can be spintrapped by the solvent to give a radical having the structure CD3-(SO2)-(NO.)-CD3. In this article, we examine this reaction for two nitramines: cyclotrimethylenetrinitramine (RDX) and hexanitrohexaazaisowurzitane (HNIW), which are energetic materials. The decay of the spin-adduct radical (I) follows first-order kinetics for both nitramines studied, having a rate constant (k) of congruent to 7.1 x 10(-4) s-1. The net growth in spin concentration of (1) measured from EPR spectra is fitted by a first-order rate equation taking into account the simultaneous competitive decay rate of spin adduct (I). Using the rate data and EPR spin concentration data, the ratio of free .NO2 produced per parent nitramine molecule is estimated as 1:1 for RDX and 4:1 for HNIW. Biological implications of trapping of .NO2 by dimethyl sulfoxide are discussed. Topics: Bridged-Ring Compounds; Deuterium; Dimethyl Sulfoxide; Electron Spin Resonance Spectroscopy; Free Radicals; Kinetics; Nitro Compounds; Nitrogen Dioxide; Photolysis; Solutions; Triazines	1993

Article

Year

Aminoxyl (nitroxyl) radicals in the early decomposition of the nitramine RDX.

The journal of physical chemistry. A, 2013, Mar-14, Volume: 117, Issue:10

The explosive nitramine RDX (1,3,5-trinitrohexahydro-s-triazine) is thought to decompose largely by homolytic N-N bond cleavage, among other possible initiation reactions. Density-functional theory (DFT) calculations indicate that the resulting secondary aminyl (R2N·) radical can abstract an oxygen atom from NO2 or from a neighboring nitramine molecule, producing an aminoxyl (R2NO·) radical. Persistent aminoxyl radicals have been detected in electron-spin resonance (ESR) experiments and are consistent with autocatalytic "red oils" reported in the experimental literature. When the O-atom donor is a nitramine, a nitrosamine is formed along with the aminoxyl radical. Reactions of aminoxyl radicals can lead readily to the "oxy-s-triazine" product (as the s-triazine N-oxide) observed mass-spectrometrically by Behrens and co-workers. In addition to forming aminoxyl radicals, the initial aminyl radical can catalyze loss of HONO from RDX.

Topics: Electron Spin Resonance Spectroscopy; Explosive Agents; Kinetics; Nitrogen Dioxide; Nitrogen Oxides; Nitrosamines; Oxygen; Quantum Theory; Thermodynamics; Triazines

2013

Spin trapping of nitrogen dioxide radical from photolytic decomposition of nitramines.

Free radical biology & medicine, 1993, Volume: 15, Issue:3

The photochemical (lambda < 400 nm) decomposition of some monocyclic and polycyclic nitramines produces .NO2, which can be detected in the respective nitramine crystals at 77 K by EPR (electron paramagnetic resonance). In solutions of perdeutero-dimethylsulfoxide (DMSO-d6) the .NO2 produced by photolytic decomposition of dissolved nitramines can be spintrapped by the solvent to give a radical having the structure CD3-(SO2)-(NO.)-CD3. In this article, we examine this reaction for two nitramines: cyclotrimethylenetrinitramine (RDX) and hexanitrohexaazaisowurzitane (HNIW), which are energetic materials. The decay of the spin-adduct radical (I) follows first-order kinetics for both nitramines studied, having a rate constant (k) of congruent to 7.1 x 10(-4) s-1. The net growth in spin concentration of (1) measured from EPR spectra is fitted by a first-order rate equation taking into account the simultaneous competitive decay rate of spin adduct (I). Using the rate data and EPR spin concentration data, the ratio of free .NO2 produced per parent nitramine molecule is estimated as 1:1 for RDX and 4:1 for HNIW. Biological implications of trapping of .NO2 by dimethyl sulfoxide are discussed.

Topics: Bridged-Ring Compounds; Deuterium; Dimethyl Sulfoxide; Electron Spin Resonance Spectroscopy; Free Radicals; Kinetics; Nitro Compounds; Nitrogen Dioxide; Photolysis; Solutions; Triazines

1993