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Numerical Calculations and Measurements of Energy Transduction in Electrically Exploded Ni/Al Laminates

Published online by Cambridge University Press:  23 January 2013

Christopher J. Morris
Affiliation:
U.S. Army Research Laboratory, 2800 Powder Mill, Rd, Adelphi, MD, 20783, USA
Paul R. Wilkins
Affiliation:
Lawrence Livermore National Laboratory, 7000 East Avenue, Livermore, CA 94550, USA
Chadd M. May
Affiliation:
Lawrence Livermore National Laboratory, 7000 East Avenue, Livermore, CA 94550, USA
Nicholas W. Piekiel
Affiliation:
U.S. Army Research Laboratory, 2800 Powder Mill, Rd, Adelphi, MD, 20783, USA
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Abstract

The electrical heating of Ni/Al laminate foils allows interrogation of phenomena at heating rates as high as 10^12 K/s. In the 2011 Fall MRS meeting, we reported on emission spectra from rapidly heated Ni/Al laminates resolved temporally over 350 ns, which provided qualitative evidence of rapid and exothermic vapor phase mixing of Ni and Al in these experiments which we term electrical explosions. These results were significant, because thermal diffusion processes normally limit Ni/Al reactions to much slower energy release rates, potentially limiting their applications. Here we present further evidence of exothermic Ni/Al mixing, quantified by experimental velocity measurements of encapsulation material and interpreted by numerical calculations of energy partitioning into different processes. These calculations agreed well with experiments from different Al, Cu, and Ni samples, sputter-deposited and lithographically patterned into bow-tie bridge structures. Velocity measurements of up to 5 km/s for 11.5 μm thick parylene encapsulation layers were accurately predicted using a single, empirical fitting parameter which depended on the electrical circuit used. The calculations also agreed with encapsulation layers accelerated by electrically exploded Ni/Al laminates as long as an additional 1.2 kJ/g of energy was included in the model. This value is precisely the enthalpy of mixing between Ni and Al, and therefore quantifies the transduction of energy into encapsulation layer kinetic energy.

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Articles
Copyright
Copyright © Materials Research Society 2013

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References

REFERENCES

Varesh, R., “Electric detonators: EBW and EFI, ” Propellants, Explos., Pyrotech. 21, 150154, (1996).10.1002/prep.19960210308CrossRefGoogle Scholar
Burden, R., Gray, J., and Oxley, C., “Explosive foil injection (EFI) pre-accelerator for electromagnetic launchers, ” IEEE Trans. Magn. 25, 107110, (Jan 1989).10.1109/20.22516CrossRefGoogle Scholar
Rosen, M. D., Hagelstein, P. L., Matthews, D. L., Campbell, E. M., Hazi, A. U., Whitten, B. L., MacGowan, B., Turner, R. E., Lee, R. W., Charatis, G., Busch, G. E., Shepard, C. L., and Rockett, P. D., “Exploding-foil technique for achieving a soft x-ray laser, ” Phys. Rev. Lett. 54, 106109, (1985).10.1103/PhysRevLett.54.106CrossRefGoogle ScholarPubMed
Stewardson, H., Novac, B., Smith, I., and Senior, P., “Empirical modelling of copper foil fuses [as pulsed power switches], ” in Proc. 10th International Pulsed Power Conference, 2, Jul. 3-6 1995, 11211125.Google Scholar
Takaki, K., Takada, Y., Itagaki, M., Mukaigawa, S., Fujiwara, T., Ohshima, S., Takahashi, I., and Kuwashima, T., “Ceramics joining using explosive metal foil, ” in Proc. 14th International Pulsed Power Conference, 2, Jun. 15-18 2003, 12581261.Google Scholar
Sedoi, V., Mesyats, G., Oreshkin, V., Valevich, V., and Chemezova, L., “The current density and the specific energy input in fast electrical explosion, ” IEEE Trans. Plasma Sci. 27, 845850, (1999).CrossRefGoogle Scholar
Sasaki, T., Nakajima, M., Kawamura, T., and Horioka, K., “Electrical conductivities of aluminum, copper, and tungsten observed by an underwater explosion, ” Phys. Plasmas 17, 084501, (2010).10.1063/1.3475430CrossRefGoogle Scholar
Morris, C. J., Mary, B., Zakar, E., Barron, S., Fritz, G., Knio, O., Weihs, T. P., Hodgin, R., Wilkins, P., and May, C., “Rapid initiation of reactions in Al/Ni multilayers with nanoscale layering, ” J. Phys. Chem. Solids 71, 8489, (2010).10.1016/j.jpcs.2009.07.026CrossRefGoogle Scholar
Morris, C. J., Wilkins, P., May, C., and Weihs, T. P., “Time-resolved emission spectroscopy of electrically heated energetic Ni/Al laminates, ” in Advances in Energetic Materials Research, MRS Fall Meeting, 2012, 1405.Google Scholar
Morris, C. J., Wilkins, P., May, C., Zakar, E., and Weihs, T. P., “Streak spectrograph temperature analysis from electrically exploded Ni/Al nanolaminates, ” Thin Solid Films 520, 16451650, (2011).10.1016/j.tsf.2011.07.043CrossRefGoogle Scholar
Morris, C. J., Wilkins, P., and May, C., “Streak spectroscopy and velocimetry of electrically exploded Ni/Al laminates, ” Journal of Applied Physics, ” (2013), in press.10.1063/1.4776731CrossRefGoogle Scholar
Sandakov, V. M., Esin, Y. O., and Gel’d, P. V., “Enthalpies of formation of molten nickel aluminum alloys at 1650°C, ” Russian Journal of Physical Chemistry 1020, 45, (1971).Google Scholar
Strand, O. T., Goosman, D. R., Martinez, C., Whitworth, T. L., and Kuhlow, W. W., “Compact system for high-speed velocimetry using heterodyne techniques, ” Rev. Sci. Instrum. 77, 083108, (2006).10.1063/1.2336749CrossRefGoogle Scholar
Gurney, R. W., “The initial velocities fo fragments from bombs, shells, and grenades, ” Ballistic Research Laboratory, Aberdeen, Maryland, Tech. Rep. BRL-405, 1943.Google Scholar
Schmidt, S. C., Seitz, W. L., and Wackerle, J., “An empirical model to compute the velocity histories of flyers driven by electrically exploding foils, ” Los Alamos National Laboratories, Tech. Rep. LA-6809, Jul. 1977.Google Scholar
Oreshkin, V. I., Barengol’ts, S. A., and Chaikovsky, S. A., “Numerical calculation of the current specific action integral at the electrical explosion of wires, ” Tech. Phys. 52, 642650, (May 2007).10.1134/S1063784207050179CrossRefGoogle Scholar