Scientific Reports (Dec 2023)

New thermal decomposition pathway for TATB

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

DOI
https://doi.org/10.1038/s41598-023-47952-6
Journal volume & issue
Vol. 13, no. 1
pp. 1 – 6

Abstract

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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 H2O is the initiating decomposition step. However, early evolving CO2 (m/z 44) along with H2O (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 CO2 has not been explained, until now. With the recent successful synthesis of 13C6-TATB (13C incorporated into the benzene ring), the same experiments have been used to show the source of the CO2 is the early breakdown of the TATB ring, not adventitious C from impurities and/or adsorbed CO2. A shift in mass m/z 44 (CO2) to m/z 45 is observed throughout the decomposition process indicating the isotopically labeled 13C ring breakdown occurs at the onset of thermal decomposition along with furazan formation. Partially labeled (N18O2)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.