Synthesis of High-Energy Materials Modified with Nanoscale Carbon and Investigation of Their Sensitivity to Laser Radiation

Synthesis of High-Energy Materials Modified with Nanoscale Carbon and Investigation of Their Sensitivity to Laser Radiation

It is found that high-energy materials (HEM), modified with nanoscale fulleroid-type carbon (astralen), such as PETN—pentaerythritol tetranitrate, LS—lead styphnate, and NCP— pentaammine (5-nitro-tetrazolato-N 2 ) cobalt(III) perchlorate, exhibit an increased susceptibility to laser diode radiation....

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Bibliographic Details
Published in:Russian journal of general chemistry Vol. 92; no. 6; pp. 1137 - 1142
Main Authors: Vedernikov, Yu. N., Fedotov, S. A., Smirnov, A. V., Avatinyan, G. A., Parshikov, Yu. G., Ponomarev, A. N., Kulagin, Yu. A.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 01-06-2022
Springer
Springer Nature B.V
Subjects:
Carbon
Chemistry
Chemistry and Materials Science
Chemistry/Food Science
Cobalt
Crystallization
Detonators
Equipment and supplies
Explosives
Fiber optics
Investigations
Isopropanol
Laser beams
Lasers
Nanoparticles
Numerical aperture
Optical fibers
Oxygen production
PETN
Photosensitivity
Radiant flux density
Radiation
Semiconductor lasers
Sensitivity
Synthesis
laser initiation
astralen
singlet excited oxygen
laser diode
high-energy modified materials
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Summary:It is found that high-energy materials (HEM), modified with nanoscale fulleroid-type carbon (astralen), such as PETN—pentaerythritol tetranitrate, LS—lead styphnate, and NCP— pentaammine (5-nitro-tetrazolato-N 2 ) cobalt(III) perchlorate, exhibit an increased susceptibility to laser diode radiation. Modified HEM were obtained by the original methods: NCP and PETN—in the crystallization process in astralen suspension and modified LS—directly in the synthesis process in the presence of astralen nanoparticles. The most efficient way to separate astralen clusters is to disperse them under intense ultrasound exposure in a liquid medium at a specific radiation intensity of at least 2–4 W/cm 3 . Therefore, to ensure the nanoscale, astralen was ultrasonicated in isopropyl alcohol or aqueous isopropyl alcohol and used as a suspension for the production of modified HEM. For the tests, we used a laser initiation system based on a laser diode on several emitting crystals with the radiation wavelength of 976 nm, maximum permissible radiation output power in the continuous mode of 60 W, and radiation coupling-out into the optical fiber with a core diameter of 105 μm and a numerical aperture of 0.15. After equipping the experimental sample of the laser blasting cap (LBC) with photosensitive HEM, the fiber-optic cable was installed in its shell, consisting of the initiating optical fiber with a diameter of 105 µm and the recording fiber with a diameter of 500 µm, each having polished ends and a common end block. The compositions were tested on the LBC model at different values of the laser diode radiation power, the radiation power density limit for HEM, both modified with astralen and standard ones of the same dispersion, was determined. It was found that the introduction of astralens into HEM contributed to a significant increase in their sensitivity to laser radiation not only due to the absorption of radiation quanta by astralen nanoparticles with the formation of “hot spots,” but also to the specific mechanism, characteristic of fulleroid nanoparticles: singlet excited oxygen production reaction.
ISSN:1070-3632
1608-3350
DOI:10.1134/S1070363222060275