Your search keyword '"Geppert-Kleinrath, H."' showing total 3 results

1. Measurements of fusion reaction history in inertially confined burning plasmas.

Author

Kim, Y., Meaney, K. D., Geppert-Kleinrath, H., Herrmann, H. W., Murphy, T. J., Young, C. S., Hoffman, N. M., Jorgenson, H. J., Morrow, T., Wilson, D. C., Loomis, E. N., Cerjan, C., Zylstra, A. B., Jeet, J., Schlossberg, D. J., Rubery, M. S., Moore, A. S., Kritcher, A. L., Carrera, J. A., and Mariscal, E. F.

Subjects

NUCLEAR fusion, CHERENKOV counters, PLASMA confinement, TRITIUM, GAS detectors, INERTIAL confinement fusion, DETECTORS

Abstract

Direct evidence of inertially confined fusion ignition appears in the abrupt temperature increase and consequent rapid increase in the thermonuclear burn rate as seen in the reaction history. The Gamma Reaction History (GRH) and Gas Cherenkov Detector (GCD) diagnostics are γ-based Cherenkov detectors that provide high quality measurements of deuterium–tritium fusion γ ray production and are, thus, capable of monitoring the thermonuclear burn rate. Temporal shifts in both peak burn time and burn width have been observed during recent high-yield shots (yields greater than 1017 neutrons) and are essential diagnostic signatures of the ignition process. While the current GRH and GCD detectors are fast enough to sense the changes of reaction history due to alpha heating, they do not have enough dynamic range to capture the onset of alpha heating. The next generation of instrumentation, GRH-15m, is proposed to increase the yield-rate coverage to measure the onset of alpha-heating. [ABSTRACT FROM AUTHOR]

Published

2023

2. Design of multi neutron-to-gamma converter array for measuring time resolved ion temperature of inertial confinement fusion implosions.

Author

Meaney, K. D., Kim, Y., Hoffman, N. M., Geppert-Kleinrath, H., Jorgenson, J., Hochanadel, M., Appelbe, B., Crilly, A., Basu, R., Saw, E. Y., Moore, A., and Schlossberg, D.

Subjects

ION temperature, INERTIAL confinement fusion, DOPPLER broadening, CHERENKOV counters, NEUTRON measurement, GAS detectors

Abstract

The ion temperature varying during inertial confinement fusion implosions changes the amount of Doppler broadening of the fusion products, creating subtle changes in the fusion neutron pulse as it moves away from the implosion. A diagnostic design to try to measure these subtle effects is introduced—leveraging the fast time resolution of gas Cherenkov detectors along with a multi-puck array that converts a small amount of the neutron pulse into gamma-rays, one can measure multiple snapshots of the neutron pulse at intermediate distances. Precise measurements of the propagating neutron pulse, specifically the variation in the peak location and the skew, could be used to infer time-evolved ion temperature evolved during peak compression. [ABSTRACT FROM AUTHOR]

Published

2022

3. Multi-pulse time resolved gamma ray spectroscopy of the advanced radiographic capability using gas Cherenkov diagnostics.

Author

Meaney, K. D., Kerr, S., Williams, G. J., Geppert-Kleinrath, H., Kim, Y., Herrmann, H. W., Kalantar, D. H., Mackinnon, A., Bowers, M., Pelz, L., Alessi, D., Martinez, D., Prantil, M., Herriot, S., Hermann, M. R., Lanier, T. E., Hamamoto, M., Di Nicola, J. M., Yang, S., and Williams, W.

Subjects

GAMMA ray spectroscopy, CHERENKOV counters, GAS detectors, PHOTON flux, ATTOSECOND pulses, X-ray spectra, TIME-resolved spectroscopy

Abstract

The advanced radiographic capability located at the National Ignition Facility (NIF) uses high intensity, short pulse lasers to create bright photon sources for diagnosing high energy density experiments. There are radiographic needs for a multi-frame time-resolved MeV gamma diagnostic for experiments on the NIF with sub-nanosecond resolution. A series of experiments demonstrated measurements of MeV x-ray spectra resolved with a time separation of a few nanoseconds through the use of gas Cherenkov detectors. A two-pulse radiographic experiment found a 30% reduction in > 2.8 MeV photon flux compared to the first frame exposure. [ABSTRACT FROM AUTHOR]

Published

2021