Split radiographic tracer technique to measure the full width of a high energy density mixing layer

Huntington, C. M.; Raman, K. S.; Nagel, S. R.; MacLaren, S. A.; Baumann, T.; Bender, J. D.; Prisbrey, S. T.; Simmons, L.; Wang, P.; Zhou, Y.

doi:10.1016/j.hedp.2019.100733

Title: Split radiographic tracer technique to measure the full width of a high energy density mixing layer

Journal Article · 25 November 2019 · High Energy Density Physics

DOI: https://doi.org/10.1016/j.hedp.2019.100733 · OSTI ID:1837815

^[1]; Raman, K. S. ^[1]; Nagel, S. R. ^[1]; MacLaren, S. A. ^[1]; Baumann, T. ^[1]; Bender, J. D. ^[1]; Prisbrey, S. T. ^[1]; Simmons, L. ^[1]; Wang, P. ^[1]; Zhou, Y. ^[1]

Lawrence Livermore National Lab. (LLNL), Livermore, CA (United States)

In this work, we describe a new radiography–based technique for measuring the width of the mixing layer that develops when high–energy–density (HED) fluids of different density mix at an interface. In a traditional radiography target, the denser material includes an embedded, density–matched, high opacity, tracer layer to focus the radiograph on a 2D slice of the 3D flow field. The high opacity layer enhances the contrast between the dense and light materials that permits a clear identification of the spike front, i.e. penetration of the dense material into the light material, but obscures the bubble front, i.e. penetration of the light material into the heavy when the fluids are highly interpenetrated, as in a turbulent mixing layer. On the other hand, removing the tracer layer makes it difficult to identify the interface at all, due to poor contrast and an increased susceptibility to edge effects. Our solution is a split tracer approach where half the target uses the traditional geometry while the other half utilizes a special tracer layer in the light material to produce a radiograph with inverse x-ray opacity characteristics when backlit at a specified x–ray energy. Hydrodynamic equivalency is maintained between the two halves of the target. By making a single target with the traditional and inverse material pairs set side-by-side, we are able to simultaneously measure the penetration of bubbles and spikes in a deeply nonlinear flow, yielding the full mix width. We discuss this new target concept and present our first experiments at the National Ignition Facility (NIF) demonstrating the viability of this technique.

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Research Organization:: Lawrence Livermore National Laboratory (LLNL), Livermore, CA (United States)

Sponsoring Organization:: USDOE; USDOE National Nuclear Security Administration (NNSA)

Grant/Contract Number:: AC52-07NA27344

OSTI ID:: 1837815

Report Number(s):: LLNL-JRNL--757667; 945507

Journal Information:: High Energy Density Physics, Journal Name: High Energy Density Physics Vol. 35; ISSN 1574-1818

Publisher:: ElsevierCopyright Statement

Country of Publication:: United States

Language:: English

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