The kinetic of thermal decomposition of PETN, Pentastite and Pentolite by TG/DTA non-isothermal methods | Health & Environmental Research Online (HERO)

HERO ID

3982801

Reference Type

Journal Article

Title

The kinetic of thermal decomposition of PETN, Pentastite and Pentolite by TG/DTA non-isothermal methods

Author(s)

Pouretedal, HR; Damiri, S; Ravanbod, M; Haghdost, M; Masoudi, S

Year

2017

Is Peer Reviewed?

1

Journal

Journal of Thermal Analysis and Calorimetry
ISSN: 1388-6150
EISSN: 1588-2926

Publisher

SPRINGER

Location

DORDRECHT

Volume

129

Issue

1

Page Numbers

521-529

Language

English

DOI

10.1007/s10973-017-6164-0

Web of Science Id

WOS:000403470800050

Abstract

The non-isothermal TG/DTA technique has been used to study the thermal decomposition of PETN, Pentastite (93:7 of PETN:wax) and Pentolite (50:50 of TNT:PETN). The DTA curves were showed an exothermic peak for decomposition of PETN and Pentastite and the exothermic double peaks for decomposition of Pentolite over the range of 150-270 A degrees C at heating rates of 4, 6, 8 and 10 K min(-1) under argon atmosphere. The double peaks in decomposition of Pentolite were related to PETN and TNT, respectively. The overlapped peaks were resolved by peak fitting procedure. Then, the activation energy (E (a)) of thermal decomposition of PETN, Pentastite and Pentolite was calculated by model-free methods of KAS, OFW and Friedman for different conversion fraction (alpha) values in the range 0.1-0.9. The pre-exponential factor and the best kinetic model for decomposition of explosives were determined by means of the compensation effect, and the selected model was confirmed by the nonlinear model-fitting method. The activation energy was 135.1-136.9, 143.6-149.2, 123.0-125.0 and 59.9-75.2 kJ mol(-1) for PETN, Pentastite and first peak of Pentolite (PETN) and second peak of Pentolite (TNT), respectively. The higher activation energy and thermal stability of Pentastite versus PETN is related to the additive paraffin wax. While, the synergic effect between two explosives in Pentolite is due to decrease of the E (a) of its components. The mechanism function of Avrami-Erofeev A (3/2), A (5/4), A (2) and A (3) was the most probable models for description of thermal decomposition reactions of PETN, Pentastite, PETN (first peak) in Pentolite and TNT (second peak) in Pentolite, respectively.

Keywords

Pentolite; Pentastite; TNT; PETN; Thermal decomposition; Activation energy