Aluminothermic Technology
Existence
of High-Tech Metal-Based Explosives from 9/11 Research
The best-known explosives are composed primarily of
nitrogen, oxygen, carbon, and hydrogen. It's not well known that powerful
explosives can be made entirely from metals and oxides of metals.
One of the critiques of theories that thermite was used to destroy the World
Trade Center skyscrapers asserts that thermite preparations don't have
sufficient explosive power to account
for
the observed features of the buildings'
destruction. This criticism seems to be uninformed by knowledge of some of the
aluminothermic preparations known to exist -- particularly those being
researched for military applications.
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Thermite
demonstration
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The typical classroom demonstration of the thermite reaction
is very pyrotechnic and heat-producing, but is not explosive. The reason for
this is that the reaction rate is too slow to cause the rapid increase in
pressure characteristic of a detonation, or sharp explosion. It's not for lack
of energy: the energy density of thermite (Al + Fe2O3) is
comparable to TNT on a weight basis, and three times as high on a volumetric
basis.
In contrast to the slow-burning behavior of low-tech
thermite preparations, various engineered forms of aluminothermic materials
apparently have explosive power resembling conventional high explosives while
retaining higher energy densities. 1 A 2005 paper presented by
scientists from the Lawrence Livermore National Laboratory claims: "We
have previously prepared pyrotechnic and explosive composites based on thermite
reactions whose fuel and oxidizer constituents are intimately
mixed on the nanometer-sized scale." 2 Contemporary aluminothermic
nanocomposite explosives apparently achieve their explosive power from a
combination of methods including: a fast reacation rate resulting from an
extremely small size of the fuel and oxidizer particles; and augmentation of blast
pressure through the presence of easily vaporized compounds such as
hydrocarbons in a matrix holding the particles in close proximity. The physical
structure of the matrix and additives to it may stabilize the preparation to
prevent it from degrading or accidentally igniting.
A since-removed document posted on the Los Alamos National
Laboratory website, under the heading 'Licensable Technologies', describes an
aluminothermic material having fast reaction rate, in which the aluminum is
oxidized by a fluorocarbon instead of a metal oxide.
Enhanced Explosive Materials Using Nano-Particulate
Metal Fuels
Summary:
Metal
fluorocarbon mixtures have been recognized since World War II as highly
reactive pyrotechnics. Their use as explosives, however, has, until recently,
been limited due to the inherently low reaction rates of the metal particles
with the fluorocarbon material. Scientists at Los Alamos National Laboratory
have discovered that these slow reaction rates can be greatly enhanced by
substituting nano-sized aluminum for the conventional micron-sized metal
powders, enabling various applications heretofore not possible with metal
fluorocarbon mixtures.
Nano-sized
aluminum acts as a burning rate modifier. Its high surface area allows for fast
chemical reactions enabling explosive, propellant, and pyrotechnic applications
that could not previously be achieved using metal fluorocarbon mixtures.
Additionally, nano-sized aluminum acts as a thickening agent, meaning that one
can use a liquid fluorocarbon as part of the mixture. The liquid fluorocarbon
completely coats the aluminum particles, while the mixture’s consistency
remains suitable for use as explosive, propellant, and pyrotechnic fill
material.
The
nano-sized aluminum and fluorocarbon mixture has a high weight and energy
density compared with standard explosives—-ideal for small and medium caliber
bullets. The burning material also produces very bright light, enabling its use
in flash devices and flares. Because the compositions ignite only at very high
temperatures, they can be used in situations that require resistance to large
swings in environmental temperature, such as in actuator applications.
Since metallic fuels have long been used in rocketry and
ballistics, there is a great deal of information on the subject that operatives
planning the 9/11 attack could draw upon. Additionally, they would be able to
take advantage of recent advances in nano-thermite research by some of the same
entities that were involved in the official WTC investigations.
By
reading NIST's responses to questions about the use of
aluminothermic incendiaries, one could get the impression that NIST's
investigators had never heard of super-thermites or nano-thermites. Their August 2006 FAQ asserts:
Thermite
burns slowly relative to explosive materials and can require several minutes in
contact with a massive steel section to heat it to a temperature that would
result in substantial weakening.
But, as Kevin Ryan points out in his July 2008 article The Top Ten Connections Between NIST and Nano-Thermites,
NIST, including its leadership, has been on the forefront of research into
advanced aluminothermic mixutures, also described as energetic nanocomposites,
metastable intermolecular composites, and superthermites.
Perhaps this explains why NIST's answers to questions about
aluminothermic arson seem so transparently disingenuous, and why NIST avoided even mentioning the material in Appendix C of FEMA's Report.
References
2. https://www.blogger.com/nullFormulation and Performance of Novel Energetic
Nanocomposites and Gas Generators Prepared by Sol-Gel Methods, www.osti.gov, March 25, 2005 [cached]
3. https://www.blogger.com/nullEnhanced
Explosive Materials Using Nano-Particulate Metal Fuels, lanl.gov,
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