New thermal decomposition pathway for TATB

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

doi:10.1038/s41598-023-47952-6

Cited by 3 publications

(2 citation statements)

References 26 publications

(49 reference statements)

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“…The NO gas may also be acting as a reducing agent as furazans form, with NO gas reacting to reduce nitrogen from NO 2 groups, and NO 2 gas reacting to oxidize amine groups as furazans form. Intramolecular electron transfer may also be driving this redox balance as furazans are formed [33]. Overall, these results suggest an auto-oxidation mechanism driven by NO 2 gas formation is a strong driver of TATB thermal decomposition.…”

Section: Thermal Decomposition Implicationsmentioning

confidence: 77%

“…The thermal decomposition lag may be caused by the kinetic barriers to releasing NO 2 groups [30]. The verification of NO 2 loss in TATB thermal decomposition products along with a weak signal measured with various mass spectrometry and vibrational spectroscopy techniques [10] suggests NO 2 molecule is highly reactive [25,[31][32][33] and may drive a portion of the TATB decomposition, resulting from a series of redox reactions, such as the oxidation of the carbon ring to CO 2 and drive the redox reactions aiding in the formation of furazans. The high reactivity may explain why it is only found in trace levels in the gas phase.…”

Section: Thermal Decomposition Implicationsmentioning

confidence: 97%

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TATB thermal decomposition: Expanding the molecular profile with cryo‐focused pyrolysis GC‐MS

Morrison,

Moore,

Coffee

et al. 2024

Propellants Explo Pyrotec

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Understanding the molecular composition of high explosives during thermal decomposition is vital for predicting the sensitivity, safety, and performance of explosive materials. The thermal decomposition of 1,3,5‐triamino‐2,4,6‐trinitrobenzene (TATB) has been linked to the formation of furazans through a series of dehydration reactions of the NO2 and NH2 groups on the phenyl ring, along with breakdown into small molecules (≤120 amu). Molecular identification of compounds formed in this transformation of the furazans to light gases has been lacking. To address this, we have applied a pseudo‐confined sampling system in a cryo‐focused pyrolysis gas chromatography‐mass spectrometry (pyGC‐MS) system to molecularly identify these intermediates. By design, sublimation of TATB, which has complicated MS analyses of thermal degradation, was significantly reduced and additional compounds were identified with potential structural information. In addition to the known furazan compounds, one of these compounds forms from the loss of oxygen from benzo‐trifurazan (F3) and produces an open ring structure that may be the first step in the formation of lower molecular weight furazan breakdown products. The loss of a nitro group from benzo‐monofurazan (F1) was also discovered and implicates the formation of oxidizing NO2 gas in the thermal decomposition mechanism. These findings are vital for understanding the proper heat flow from energetic materials on a molecular level, necessary when measuring enthalpy and developing decomposition models based on kinetic parameters.

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Section: Thermal Decomposition Implicationsmentioning

confidence: 77%

Section: Thermal Decomposition Implicationsmentioning

confidence: 97%

TATB thermal decomposition: Expanding the molecular profile with cryo‐focused pyrolysis GC‐MS

Morrison,

Moore,

Coffee

et al. 2024

Propellants Explo Pyrotec

Self Cite

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TATB thermal decomposition: An improved kinetic model for explosive safety analysis

Moore,

Morrison,

Burnham

et al. 2023

Propellants Explo Pyrotec

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We investigate and model the cook‐off behavior of 1,3,5‐triamino‐2,4,6‐trinitrobenzene (TATB) to understand the response of explosive systems in abnormal thermal environments. Decomposition has been explored via conventional ODTX (one‐dimensional time‐to‐explosion), PODTX (ODTX with pressure‐measurement), PyGC‐MS (pyrolysis gas chromatography mass spectrometry), TGA (thermo‐gravimetric analysis), DSC (differential scanning calorimetry), and IR (infrared spectroscopy) experiments under isothermal and ramped temperature profiles. The data were used to fit rate parameters for proposed reaction schemes in a MATLAB thermo‐chemical computational model. These parameterizations were carried out utilizing a genetic algorithm optimization method on LLNL's high‐performance computing clusters, which enabled significant parallelization. These results include a multi‐step reaction decomposition model, identification of likely autocatalytic gas‐phase species, accurate high‐temperature sensitization, and prediction of confined system pressurization. This model will be scalable to several applications involving TATB‐based explosives, like LX‐17, including thermal safety models of full‐scale systems.

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