Understanding the transport and break up of reactive ejecta

In this paper, we investigate reactive- versus hydrodynamic-breakup processes of ejecta. For this study, the reactive metal is cerium (Ce) and the nonreactive metal is tin (Sn), the nonreactive gas is helium (He) and the reactive gas is deuterium (D2) or hydrogen (H2). Experiments were performed in...

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Bibliographic Details
Published in:Physica. D 2020-01, Vol.415
Main Authors: Buttler, William Tillman, Schulze, Roland K., Charonko, John J., Cooley, Jason C., Hammerberg, James E., Schwarzkopf, John D., Sheppard, Daniel G., Goett, III, Johnny J., Grover, Michael, La Lone, Brandon M., Lamoreaux, Stephen K., Manzanares, Ruben, Martinez, John Israel, Regele, Jonathan D., Schauer, Martin M., Schmidt, Derek W., Stevens, Gerald D., Turley, William D., Valencia, Ruben J.
Format: Article
Language:English
Subjects:
chemically reactive- and non-reactive ejecta
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
ejecta
ejecta transport
hydrodynamic particle transport breakup processes
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
MATERIALS SCIENCE
reactive particle transport breakup processes
Reactive- and non-reactive ejecta
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Summary:In this paper, we investigate reactive- versus hydrodynamic-breakup processes of ejecta. For this study, the reactive metal is cerium (Ce) and the nonreactive metal is tin (Sn), the nonreactive gas is helium (He) and the reactive gas is deuterium (D2) or hydrogen (H2). Experiments were performed in vacuum and the reactive- and nonreactive-gases at various pressures, where we endeavored to match the post-shock gas densities to differentiate between reactive- versus hydrodynamic-breakup processes. Hydrodynamic breakup sensitively links to the Weber number (gas density, liquid fragment diameter, surface tension, and the square of the relative velocity between the fragment and the gas), whereas reactive breakup links to the reactive dynamics which includes two processes. In one case the reactive metal breaks up into smaller fragments as rapidly as the reaction rate, and in the other a crust grows on the liquid fragments as the reactions occur, a diffusion limited process. In the latter case, the particle diameters increase with time as the crust grows. In this process, which is indicated by the data, particles breakup as the CeD2 loses strength with increasing temperature, leaving an exponentially increasing diameter.
ISSN:0167-2789
1872-8022