Certain explosives may soon get a little greener and a little more precise.
LLNL researchers added unique green solvents (ionic liquids) to an explosive called TATB (1,3,5-triamino-2,4,6-trinitrobenzene) and improved the crystal quality and chemical purity of the material.
Fluoride ionic liquid as a novel super-efficient solvent can lead to high-quality single crystals of technologically important materials. The molecules in red, white, blue and gray are the explosive, TATB. The green balls (fluoride anions) and the gray and blue sticks (cations), act as the solvent. The rocks in the background are TATB crystals.
This work, supported under the Transformational Materials Initiative (TMI) Laboratory Research and Development project, appears on the cover of the Sept. 1 issue of the journal Physical Chemistry Chemical Physics.
“Improving crystal quality and purity leads to explosive materials that are safer (less likely to react violently) when subjected to mechanical impact or heat,” says Larry Fried, the project’s principal investigator and a co-author of the paper.
Most explosives belong to a general class of materials called molecular crystals, which have become important building blocks in a number of other applications ranging from drugs, pigments, agrochemicals, dyes and optoelectronics. Many of these materials, including TATB, are bound together by a strong network of hydrogen-bonds. This extended network often makes these materials nearly insoluble in common organic solvents, leading to poor quality and limited size crystals, which in turn hinders progress in many technological applications.
So the TMI team looked for a suitable alternative, which happened to be ionic liquids—a special type of molten salt that becomes liquid under the boiling point of water (100°C). Chemists recently became interested in ionic liquids because they are solvents with almost no vapor pressure, and do not evaporate, even under high temperature conditions. They also provide researchers an endless number of choices due to the large combinations of positive and negative ions involved.
Scanning electron micrograph (SEM) images of TATB crystallites: (left) commercially available TATB (Aerojet, Inc.); and (right) re-crystallized from ionic liquid.
To narrow the choices down, lead author Amitesh Maiti used state-of-the-art quantum mechanical simulations to identify a special class of ionic liquids containing fluoride anions that are highly effective in dissolving hydrogen-bonded materials such as TATB. (An anion is an atom with a net negative charge, i.e., more electrons than protons.)
“The design of custom solvents through first principles modeling opens up new possibilities for the dissolution of materials that are hard to dissolve,” Maiti says.
The next step involved an experimental team, led by Phil Pagoria, who was successful not only in dissolving TATB in such solvents, but also in growing large defect-free crystallites (more than 97% pure TATB), which will lead to a better formulated material for explosive applications.
A TATB molecule along with its COSMO solvation surface.
The solvents and the dissolution process developed by the TMI team have applications in other fields as well, such as the production of polymers (plastics) or molecular solids (pharmaceuticals, paints, propellants, explosives). For instance, the team found that fluoride ionic liquids are highly effective in dissolving cellulose (plant fiber), a versatile bio-renewable polymeric material with many applications.
However, the immediate goal is to find a cost-effective way to improve the quality of low purity TATB. TATB is an extremely safe explosive that is used by the Dept. of Energy, the Dept. of Defense and the mining industry.
Other Livermore researchers include: Alex Gash, Yong Han, Christine Orme and Richard Gee.
