Thermal history sensing inside high-explosive environments using thermoluminescent microparticles

Merlin L Mah; Philip R Armstrong; Sangho S. Kim; Joel R. Carney; James M. Lightstone; Joseph J Talghader

doi:10.1109/ICSENS.2011.6127292

Thermal history sensing inside high-explosive environments using thermoluminescent microparticles

Merlin L Mah, Philip R Armstrong, Sangho S. Kim, Joel R. Carney, James M. Lightstone, Joseph J Talghader

Electrical and Computer Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

7 Scopus citations

Abstract

Thermoluminescent LiF:Mg,Ti (TLD-100) microparticle sensors are demonstrated to record the thermal history of the region near a detonated high explosive. Microparticles were gamma-irradiated to fill their charge-carrier traps and then exposed to the detonation of 20 g of a plastic bonded explosive formulation containing HMX and Al particles at a test distance of approximately 22 cm from the center of the detonation. The thermal history was reconstructed by measuring the thermoluminescent signature of the traps and matching it to appropriate models. The trap populations derived from luminescence measurements and modeling indicate that the particles experienced a maximum temperature of 240°C, then cooled to 1°C above ambient temperature within 0.4 seconds. The resulting glow curve intensity is calculated to match the observed post-detonation signal to 3% averaged over the comparison values used for reconstruction.

Original language	English (US)
Title of host publication	IEEE Sensors 2011 Conference, SENSORS 2011
Pages	1269-1272
Number of pages	4
DOIs	https://doi.org/10.1109/ICSENS.2011.6127292
State	Published - Dec 1 2011
Event	10th IEEE SENSORS Conference 2011, SENSORS 2011 - Limerick, Ireland Duration: Oct 28 2011 → Oct 31 2011

Publication series

Name	Proceedings of IEEE Sensors

Other

Other	10th IEEE SENSORS Conference 2011, SENSORS 2011
Country	Ireland
City	Limerick
Period	10/28/11 → 10/31/11

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10.1109/ICSENS.2011.6127292

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Thermal history sensing inside high-explosive environments using thermoluminescent microparticles. / Mah, Merlin L; Armstrong, Philip R; Kim, Sangho S.; Carney, Joel R.; Lightstone, James M.; Talghader, Joseph J.

IEEE Sensors 2011 Conference, SENSORS 2011. 2011. p. 1269-1272 6127292 (Proceedings of IEEE Sensors).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Mah, ML, Armstrong, PR, Kim, SS, Carney, JR, Lightstone, JM & Talghader, JJ 2011, Thermal history sensing inside high-explosive environments using thermoluminescent microparticles. in IEEE Sensors 2011 Conference, SENSORS 2011., 6127292, Proceedings of IEEE Sensors, pp. 1269-1272, 10th IEEE SENSORS Conference 2011, SENSORS 2011, Limerick, Ireland, 10/28/11. https://doi.org/10.1109/ICSENS.2011.6127292

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title = "Thermal history sensing inside high-explosive environments using thermoluminescent microparticles",

abstract = "Thermoluminescent LiF:Mg,Ti (TLD-100) microparticle sensors are demonstrated to record the thermal history of the region near a detonated high explosive. Microparticles were gamma-irradiated to fill their charge-carrier traps and then exposed to the detonation of 20 g of a plastic bonded explosive formulation containing HMX and Al particles at a test distance of approximately 22 cm from the center of the detonation. The thermal history was reconstructed by measuring the thermoluminescent signature of the traps and matching it to appropriate models. The trap populations derived from luminescence measurements and modeling indicate that the particles experienced a maximum temperature of 240°C, then cooled to 1°C above ambient temperature within 0.4 seconds. The resulting glow curve intensity is calculated to match the observed post-detonation signal to 3% averaged over the comparison values used for reconstruction.",

author = "Mah, {Merlin L} and Armstrong, {Philip R} and Kim, {Sangho S.} and Carney, {Joel R.} and Lightstone, {James M.} and Talghader, {Joseph J}",

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AU - Mah, Merlin L

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AU - Talghader, Joseph J

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AB - Thermoluminescent LiF:Mg,Ti (TLD-100) microparticle sensors are demonstrated to record the thermal history of the region near a detonated high explosive. Microparticles were gamma-irradiated to fill their charge-carrier traps and then exposed to the detonation of 20 g of a plastic bonded explosive formulation containing HMX and Al particles at a test distance of approximately 22 cm from the center of the detonation. The thermal history was reconstructed by measuring the thermoluminescent signature of the traps and matching it to appropriate models. The trap populations derived from luminescence measurements and modeling indicate that the particles experienced a maximum temperature of 240°C, then cooled to 1°C above ambient temperature within 0.4 seconds. The resulting glow curve intensity is calculated to match the observed post-detonation signal to 3% averaged over the comparison values used for reconstruction.

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Thermal history sensing inside high-explosive environments using thermoluminescent microparticles

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