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Energetic Materials Development at Technanogy Materials Development

Published online by Cambridge University Press:  01 February 2011

Kevin C. Walter ,
Christopher E. Aumann ,
R. Douglas Carpenter ,
Edward H. O'Neill  and
David R. Pesiri
Kevin C. Walter
Affiliation:
Technanogy Materials Development, LLC, 2221 Cape Cod Way, Santa Ana, CA 92703–3563
Christopher E. Aumann
Affiliation:
Technanogy Materials Development, LLC, 2221 Cape Cod Way, Santa Ana, CA 92703–3563
R. Douglas Carpenter
Affiliation:
Technanogy Materials Development, LLC, 2221 Cape Cod Way, Santa Ana, CA 92703–3563
Edward H. O'Neill
Affiliation:
Technanogy Materials Development, LLC, 2221 Cape Cod Way, Santa Ana, CA 92703–3563
David R. Pesiri
Affiliation:
Technanogy Materials Development, LLC, 2221 Cape Cod Way, Santa Ana, CA 92703–3563
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Abstract

An energetic material has been routinely manufactured from nano-metric powders of aluminum (Al) and molybdenum trioxide (MoO3). When optimized, the burn-rate of these materials (∼400 m/s) exceeds that of conventional thermites (based on micron-sized powders), but is less than that of conventional explosives. Similar burn-rates around 350 m/s are measured for these “super-thermites” using n-Al powder in the size range between 30 and 90 nm in diameter (20–60 m2/g, 60–80 wt%Al) and an oxygen to fuel (O/F) mass ratio of 1.4. The burn-rate decreases when the surface area of the MoO3 is decreased from 64 to 40 m2/g, or when O/F is changed from 1.2. Thus, for each average particle diameter, there is an optimum burn-rate at an O/F ratio that depends on the wt%Al present in the material and the particle size distribution of the powder. The burn-rate is dependent on several materials and processing factors such as the quality of the nano-metric ingredients, the processing method, and exposure to air and light, so the effect of aging and environmental exposure on the individual ingredients has been investigated. The results of this powder aging study suggests that the surface area of n-MoO3 can decrease two-fold within 10–12 days, and the Al-metal content in n-Al can decrease as much as 50% over two years. Adequate handling and storage procedures must therefore be followed for the effective use of nano-metric powders and their super-thermite mixes.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 800: Symposium AA – Synthesis, Characterization, and Properties of Energetic/Reactive Nanomaterials , 2003 , AA1.3
Copyright
Copyright © Materials Research Society 2004

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References

REFERENCES

1. U.S. Patent 5,717,159.Google Scholar
2. Son, S.F., Hiskey, M.A., Naud, D.L., Busse, J.R., and Asay, B.W., Proceedings of the International Pyrotechnics Society, The Twenty-Ninth International Pyrotechnics Seminar, pp. 871877, Westminster, Colorado, July 14–19, 2002.Google Scholar
3. Peterson, P.D., Mang, J.T., Son, S.F., Asay, B.W., Fletcher, M.F., Hjelm, R.P., and Roemer, E.L., Proceedings of the International Pyrotechnics Society, The Twenty-Ninth International Pyrotechnics Seminar, pp. 569581, Westminster, Colorado, July 14–19, 2002.Google Scholar
4. Son, S.F., Busse, J.R., Asay, B.W., Peterson, P.D., Mang, J.T., Bockmon, B., and Pantoya, M., Proceedings of the Internationl Pyrotechnics Society, The Twenty-Ninth International Pyrotechnics Seminar, pp. 203212, Westminster, Colorado, July 14–19, 2002.Google Scholar
5. Bockman, B., Son, S.F., Asay, B.W., Busse, J.R., Peterson, P.D., Mang, J.T., and Pantoya, M., 38th Combustion Subcommittee Proceedings, JANNAF, Destin, FL, April 4–8, 2002.Google Scholar
6. Son, S.F., Asay, B.W., Busse, J.R., Jorgensen, B.S., Bockman, B., and Pantoya, M., Proceedings of the International Pyrotechnics Society, The Twenty-Eighth International Pyrotechnics Seminar, Adelaide, Australia, November 4–9, 2001.Google Scholar
7. Pesiri, D., Aumann, C.E., Bilger, L., Booth, D., Carpenter, R.D., Dye, R., O’Neill, E., Shelton, D., and Walter, K.C., “Industrial Scale Nano-Aluminum Powder Manufacturing,” submitted to the Journal of Pyrotechnics, published by the Journal of Pyrotechnics, Inc., Whitewater, CO, 2003.Google Scholar
8. Bockman, B.S., Pantoya, M.L., Son, S.F., Asay, B.W., and Mang, J.T., “Burn Rates and Propagation Mechanisms of Metastable Intermolecular Composites,” submitted to Combustion and Flame, Oct. 2003.Google Scholar
9. Higa, K.T., Bliss, D.E., and Johnson, C.E., “Aging of Nanoscale Aluminum Powders and Composites,” submitted to Propellants, Explosives and Pyrotechnics, 2003.Google Scholar