Erythritol tetranitrate
Erythritol tetranitrate is an explosive compound chemically similar to PETN, though it is thought to be slightly more sensitive to friction and impact.
Like many nitrate esters, ETN acts as a vasodilator, and was the active ingredient in Cardilate tablets. Ingestion of or prolonged skin contact with ETN can lead to what is known as a nitro headache.
History
ETN was discovered by John Stenhouse in 1849 by nitrating erythritol he recently discovered. He described its explosive properties but suggested an incorrect formula due to atomic weights not yet being accurately determined.Its vasodilator properties have been researched since 1895.
DuPont researched the explosive after the war, getting a patent in 1928, but it was never commercialized due to the difficulty of erythritol synthesis. Only due to genetically-engineered yeasts in the 1990s did it become possible for the carbohydrate to become widely available.
Properties
ETN has a relatively high velocity of detonation of at a density of ). It is white in color and odorless. ETN is commonly cast into mixtures with other high explosives. ETN dissolves readily in acetone and other ketone solvents. The impact and friction sensitivity is slightly higher than the sensitivity of pentaerythritol tetranitrate. The sensitivity of melt cast and pressed ETN is comparable. Lower nitrates of erythritol, such as erythritol trinitrate, are soluble in water, so they do not contaminate most ETN samples.
Much like PETN, ETN is known for having a very long shelf life. Studies that directly observed the crystalline structure saw no signs of decomposition after four years of storage at room temperature. ETN has a melting point of, compared to PETN which has a melting point of. Recent studies of ETN decomposition suggested a unimolecular rate-limiting step in which the bond is cleaved and begins the decomposition sequence.
Even small samples of ETN on the order of can cause relatively powerful explosions verging on detonation when heated without confinement, e.g. when placed on a layer of aluminium foil and heated with flame from below.
ETN can be melt-cast in warm water. Slight decomposition is possible. No reports of runaway reactions leading to explosion have been confirmed. However, the handling sensitivity in molten state is extremely poor and it makes melt-casting it impractical for commercial applications.
Melt-cast ETN, if cooled down slowly over a period of 10–30 minutes, has a density of, detonation velocity of, and Pcj detonation pressure of about. Its brisance is far higher than that of Semtex.
Mixtures of 50:50 PETN:ETN have P slightly above and detonation velocity above. This is close to the maximum of fielded military explosives like LX-10 or EDC-29.
ETN is often plasticized using PIB/synthetic oil binders or using liquid nitric esters. The PIB-based plastic explosives are nontoxic and completely comparable to C4 or Semtex with P of, depending on density. EGDN/ETN/NC systems are toxic to touch, quite sensitive to friction and impact, but generally slightly more powerful than C4 and more powerful than Semtex with P of about and E of about. Note that explosion modeling software and experimental tests will yield absolute detonation pressures that can vary by 5% or more with the relative proportions being maintained. Erythritol tetranitrate can form eutectic mixtures with a variety of explosive compounds, including TNT, PETN, mannitol hexanitrate, and 1,3,5-trinitrobenzene.
Melt-cast ETN gives invalid results in the Hess test, i.e. the deformation is greater than 26 mm, with the lead cylinder being completely destroyed. Semtex 1A gives only 21 mm in the same test, i.e. melt-cast ETN is at least 20% more brisant than Semtex 1A.
Melt-cast ETN or high density/low inert content ETN plastic explosives are one of the materials on "watch-lists" for terrorism.
Oxygen balance
One positive characteristic of ETN that PETN does not possess is a positive oxygen balance, which means that ETN possesses more than enough oxygen in its structure to fully oxidize all of its carbon and hydrogen upon detonation. This can be seen in the schematic chemical equation below:Whereas PETN decomposes to:
The carbon monoxide still requires oxygen to complete oxidation to carbon dioxide. A detailed study of the decomposition chemistry of ETN has been recently elucidated.
Thus, for every two moles of ETN that decompose, one free mole of is released. This oxygen could be used to oxidize an added metal dust, or an oxygen-deficient explosive, such as TNT or PETN. The extra oxygen from the ETN oxidizes the carbon monoxide to carbon dioxide :