PLX

PLX, or Picatinny Liquid Explosive, is a liquid binary explosive, a mixture of 95% nitromethane (NM) along with 5% ethylene diamine (EDA) as a sensitizer. Other amine compounds can be used instead of ethylene diamine, such as triethylene tetramine or ethanolamine, but EDA has been found to be most effective. PLX is a fairly powerful high explosive, marginally exceeding the destructive yield of TNT.

Properties

PLX, when mixed, is a transparent liquid with a yellowish tint. Ethylene diamine is very volatile, requiring the contents to be sealed if any storage is intended. Generally, for safety purposes, the contents are transported separately and mixed on site. PLX is known to have a velocity of detonation (VoD) of anywhere between 6,000 and 7,000 m/s, depending on diameter. Although greatly sensitized by the addition of EDA, PLX still requires a powerful blasting cap or a small booster charge to successfully detonate.

Uses and discovery

PLX was invented during World War II by the Picatinny Arsenal in New Jersey. It was originally designed to clear minefields by being spread via plane over the targeted area or poured from a safe distance and detonated by troops on the ground.

This explosive can also be gelled through the addition of nitrocellulose, ETN, or any number of soluble nitrate esters or gelling agents. This allows for powdered metals, such as aluminum or magnesium, to be suspended in the mixture. The metal powders act as fuel, increasing heat and energy output but lowering the brisance and VoD. The result is a more sustained blast wave and a "push and heave" effect, desirable for thermobaric purposes. TrzciƄski reports that 200 grams of a mixture of NM with PMMA as gelling agent and AlMg (45:55, mean particle size = 63 microns) as fuel, in a ratio of 67.2/2.8/30 by mass, has a peak overpressure of 120 kPa 2 m from the(open air) blast site, a 1.65 TNT equivalency in peak pressure, and a 1.62 equivalency in shockwave impulse.[1] As a reference, 104 kPa is widely regarded as a pressure where 50 % of eardrums fail.[2] It's still 3 - 5 times less than the pressure needed to achieve a 50 % fatality rate via pulmonary injury as per Bass/Bowen equations (standing adult, facing any direction).[3]

PLX has been implicated as one of the materials capable of being used in catastrophic terrorism, as most steel core columns can not withstand the detonation of 10 - 30 kg PLX in direct contact (explosive on bare steel). Nitromethane and its gelling agents are freely sold to the public in the US, though. Its sale to the public has been banned in the EU in september 2014.[4]


It was the supposed explosive used in the film Die Hard with a Vengeance. However, the film grossly exaggerated the sensitivity of this explosive mixture.

PLX was one of the explosives used to down Korean Air Flight 858 along with C-4.

gollark: Sandy Bridge was 2011, and Intel is widely regarded as having not really done much since then until pretty recently.
gollark: I mean, I suppose it could maybe make sense if the original one was a bad dual-core and the new one is hexacore and they didn't run it long enough for it to thermally throttle horribly.
gollark: Intel CPUs haven't,except in core count.
gollark: Not really.
gollark: A quadrupling of CPU power in Mac Minis 7 years apart seems... unlikely, honestly?

References

  1. Cho, Sung-Il; Gao, Simon S.; Xia, Anping; Wang, Rosalie; Salles, Felipe T.; Raphael, Patrick D.; Abaya, Homer; Wachtel, Jacqueline; Baek, Jongmin; Jacobs, David; Rasband, Matthew N.; Oghalai, John S. (2013). "Mechanisms of Hearing Loss after Blast Injury to the Ear". PLOS ONE. 8 (7): e67618. Bibcode:2013PLoSO...867618C. doi:10.1371/journal.pone.0067618. PMC 3698122. PMID 23840874.
  2. Cho, Sung-Il; Gao, Simon S.; Xia, Anping; Wang, Rosalie; Salles, Felipe T.; Raphael, Patrick D.; Abaya, Homer; Wachtel, Jacqueline; Baek, Jongmin; Jacobs, David; Rasband, Matthew N.; Oghalai, John S. (2013). "Mechanisms of Hearing Loss after Blast Injury to the Ear". PLOS ONE. 8 (7): e67618. Bibcode:2013PLoSO...867618C. doi:10.1371/journal.pone.0067618. PMC 3698122. PMID 23840874.
  3. https://www.ffi.no/no/Rapporter/2012%20-%2000539.pdf
  4. https://ec.europa.eu/home-affairs/sites/homeaffairs/files/what-we-do/policies/crisis-and-terrorism/explosives/explosives-precursors/docs/guidelines_on_the_marketing_and_use_of_explosives_precursors_en.pdf
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