248 Synthetic Routes toN-Nitro
higher performance of HMX compared to RDX is offset by its higher cost of production. Conse-
quently, HMX has been restricted to military use where it has found application as a component
of some high performance propellants and powerful explosive compositions. Octol is a cast ex-
plosive containing HMX (75 %) and TNT (25 %), whereas Octal consists of wax-desensitized
HMX (70 %) and aluminium powder (30 %) and is pressed into charges. HMX has also been in-
corporated into some high performance plastic bonded explosives (PBXs). One such explosive,
PBX-9404, contains 94 % HMX, 3 % nitrocellulose and 3 % tris(chloroethyl)phosphate.
HMX can be synthesized from hexamine by any of the routes discussed below. Both methods
5.15.2.1 and 5.15.2.2 have been used for the industrial synthesis of HMX. However, the
recent commercial availability of dinitrogen pentoxide means that method 5.15.2.3 is achieving
industrial importance.
5.15.2.1 Synthesis of HMX from the nitrolysis of hexamine
Variations in the conditions used for the nitrolysis of hexamine have a profound effect on the
nature and distribution of isolated products, including the ratio of RDX to HMX. It has been
shown that lower reaction acidity and a reduction in the amount of ammonium nitrate used in
the Bachmann process increases the amount of HMX formed at the expense of RDX.^196 ,^207
Bachmann and co-workers^208 were able to tailor the conditions of hexamine nitrolysis to
obtain an 82 % yield of a mixture containing 73 % HMX and 23 % RDX. Continued efforts
to provide a method for the industrial synthesis of HMX led Castorina and co-workers^187 to
describe a procedure which produces a 90 % yield of a product containing 85 % HMX and
15 % RDX. This procedure conducts nitrolysis at a constant reaction temperature of 44◦C
and treats hexamine, in the presence of a trace amount of paraformaldehyde, with a mixture
of acetic acid, acetic anhydride, ammonium nitrate and nitric acid. Bratia and co-workers^209
used a three stage ‘aging process’ and a boron trifluoride catalyst to obtain a similar result. A
procedure reported by Picard^210 uses formaldehyde as a catalyst and produces a 95 % yield of
a product containing 90 % HMX and 10 % RDX.
The different solubilities of HMX and RDX in organic solvents means that pure HMX is
easily isolated from RDX–HMX mixtures; the higher solubility of RDX in acetone means that
recrystallization of such mixtures from hot acetone yields pure HMX.^187 ,^207
5.15.2.2 Synthesis of HMX from the nitrolysis of DPT
CH 2NNH 2 C CH 2H 2 C CH 2O 2 N N NO 2
NNNN
O 2 N NO 2O 2 N NO 2(CH 2 ) 6 N 4
104239
(DPT)see text see text3
(HMX)nitrolysis nitrolysis
NFigure 5.106HMX (3) can be synthesized from the nitrolysis of 1,5-dinitroendomethylene-1,3,5,7-
tetraazacyclooctane (DPT) (239). Wright and co-workers^189 reported that the reaction of