Within the High Energy Density Matterresearch program, run by the U.S. Air Force since 1986, systematic attempts to approach polynitrogen compounds began in 1998, when Air Force Research Laboratory at Edwards AFB became interested in researching alternatives to the highly toxic hydrazine-based rocket fuel and simultaneously funded several such proposals. Karl O. Christe, then, a senior investigator at AFRL, chose to attempt building linear out of and, based on the proposed bond structure: The reaction succeeded, and was created in sufficient quantities to be fully characterized by NMR, IR and Raman spectroscopyin 1999. The salt was highly explosive, but when was replaced by, a stronger Lewis acid, much more stable was produced, shock-resistant and thermally stable up to 60–70 °C. This made bulk quantities, easy handling, and X-ray crystal structure analysis possible.
Preparation
Reaction of and in dry at −78 °C is the only known method so far:
Chemistry
is capable of oxidizing water, NO, and, but not or ; its electron affinity is 10.44 eV. For this reason, must be prepared and handled in a dry environment: Due to stability of the fluoroantimonate, it is used as the precursor for all other known salts, typically accomplished by metathesis reactions in non-aqueous solvents such as HF,,, or acetonitrile|, where suitable hexafluoroantimonates are insoluble: The most stable salts of decompose when heated to 50–60 °C:,, and, while the most unstable salts that were obtained and studied, and were extremely shock and temperature sensitive, exploding in solutions as dilute as 0.5 mmol. A number of salts, such as fluoride, azide, nitrate, or perchlorate, cannot be formed.
Structure and bonding
In valence bond theory, pentazenium can be described by six resonance structures: where the last three pictured have smaller contributions to the overall structure because they have less favorable formal charge states than the first three. According to both ab initio calculations and the experimental X-ray structure, the cation is planar, symmetric, and approximately V-shaped, with bond angles 111° at the central atom and 168° at the second and fourth atoms. The bond lengths for N1–N2 and N4–N5 are 1.10 Å and the bond lengths N2–N3 and N3–N4 are 1.30 Å.