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New thermal decomposition pathway for TATB

Keith D. Morrison, Ana Racoveanu, Jason S. Moore, Alan K. Burnham, Batikan Köroğlu, Keith R. Coffee, Adele F. Panasci‐Nott, Gregory L. Klunder, Brad A. Steele, M A McClelland, John G. Reynolds

2023Scientific Reports15 citationsDOIOpen Access PDF

Abstract

Abstract Understanding the thermal decomposition behavior of TATB (1,3,5-triamino-2,4,6-trinitrobenzene) is a major focus in energetic materials research because of safety issues. Previous research and modelling efforts have suggested benzo-monofurazan condensation producing H 2 O is the initiating decomposition step. However, early evolving CO 2 (m/z 44) along with H 2 O (m/z 18) evolution have been observed by mass spectrometric monitoring of head-space gases in both constant heating rate and isothermal decomposition studies. The source of the CO 2 has not been explained, until now. With the recent successful synthesis of 13 C 6 -TATB ( 13 C incorporated into the benzene ring), the same experiments have been used to show the source of the CO 2 is the early breakdown of the TATB ring, not adventitious C from impurities and/or adsorbed CO 2 . A shift in mass m/z 44 (CO 2 ) to m/z 45 is observed throughout the decomposition process indicating the isotopically labeled 13 C ring breakdown occurs at the onset of thermal decomposition along with furazan formation. Partially labeled (N 18 O 2 ) 3 -TATB confirms at least some of the oxygen comes from the nitro-groups. This finding has a significant bearing on decomposition computational models for prediction of energy release and deflagration to detonation transitions, with respect to conditions which currently do not recognize this oxidation step.

Topics & Concepts

TATBThermal decompositionDecompositionChemistryExplosive materialOrganic chemistryDetonationEnergetic Materials and CombustionThermal and Kinetic AnalysisChemical Thermodynamics and Molecular Structure
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