Your search keyword '"Sio, H."' showing total 5 results

1. The phase-2 particle x-ray temporal diagnostic for simultaneous measurement of multiple x-ray and nuclear emission histories from OMEGA implosions (invited).

Author

Kabadi, N., Adrian, P., Stoeckl, C., Sorce, A., Sio, H. W., Bedzyk, M., Evans, T., Ivancic, S., Katz, J., Knauer, J., Pearcy, J., Weiner, D., Betti, R., Birkel, A., Cao, D., Johnson, M. Gatu, Regan, S. P., Petrasso, R. D., and Frenje, J.

Subjects

X-rays, NEUTRON counters, INERTIAL confinement fusion, TRITIUM, DATA quality

Abstract

Electron-temperature (Te) measurements in implosions provide valuable diagnostic information, as Te is negligibly affected by residual flows and other non-thermal effects unlike ion-temperature inferred from a fusion product spectrum. In OMEGA cryogenic implosions, measurement of Te(t) can be used to investigate effects related to time-resolved hot-spot energy balance. The newly implemented phase-2 Particle X-ray Temporal Diagnostic (PXTD) utilizes four fast-rise (∼15 ps) scintillator-channels with distinct x-ray filtering. Titanium and stepped aluminum filtering were chosen to maximize detector sensitivity in the 10–20 keV range, as it has been shown that these x rays have similar density and temperature weighting to the emitted deuterium–tritium fusion neutrons (DTn) from OMEGA Cryo-DT implosions. High quality data have been collected from warm implosions at OMEGA. These data have been used to infer spatially integrated Te(t) with <10% uncertainty at peak emission. Nuclear and x-ray emission histories are measured with 10 ps relative timing uncertainty for x rays and DTn and 12 ps for x rays and deuterium- H e 3 protons (D3Hep). A future upgrade to the system will enable spatially integrated Te(t) with 40 ps time-resolution from cryogenic DT implosions. [ABSTRACT FROM AUTHOR]

Published

2022

2. Diagnosing plasma magnetization in inertial confinement fusion implosions using secondary deuterium-tritium reactions.

Author

Sio, H., Moody, J. D., Ho, D. D., Pollock, B. B., Walsh, C. A., Lahmann, B., Strozzi, D. J., Kemp, G. E., Hsing, W. W., Crilly, A., Chittenden, J. P., and Appelbe, B.

Subjects

*INERTIAL confinement fusion, *MONTE Carlo method, *MAGNETIZATION, *TRITIUM, *ENERGY dissipation, *CHEMICAL yield, *MAGNETIC fields, *PLASMA dynamics

Abstract

Diagnosing plasma magnetization in inertial confinement fusion implosions is important for understanding how magnetic fields affect implosion dynamics and to assess plasma conditions in magnetized implosion experiments. Secondary deuterium–tritium (DT) reactions provide two diagnostic signatures to infer neutron-averaged magnetization. Magnetically confining fusion tritons from deuterium–deuterium (DD) reactions in the hot spot increases their path lengths and energy loss, leading to an increase in the secondary DT reaction yield. In addition, the distribution of magnetically confined DD-triton is anisotropic, and this drives anisotropy in the secondary DT neutron spectra along different lines of sight. Implosion parameter space as well as sensitivity to the applied B-field, fuel ρR, temperature, and hot-spot shape will be examined using Monte Carlo and 2D radiation-magnetohydrodynamic simulations. [ABSTRACT FROM AUTHOR]

Published

2021

3. A multi-channel x-ray temporal diagnostic for measurement of time-resolved electron temperature in cryogenic deuterium–tritium implosions at OMEGA.

Author

Kabadi, N., Sorce, A., Stoeckl, C., Sio, H. W., Adrian, P., Bedzyk, M., Frenje, J., Katz, J., Knauer, J., Pearcy, J., Weiner, D., Aguirre, B. A., Betti, R., Birkel, A., Cao, D., Gatu Johnson, M., Patel, D., Petrasso, R. D., and Regan, S. P.

Subjects

INERTIAL confinement fusion, ELECTRON temperature measurement, TRITIUM, X-rays, ION temperature, NEUTRONS

Abstract

Electron-temperature (Te) measurements in implosions provide valuable diagnostic information, as Te is unaffected by residual flows and other non-thermal effects unlike ion temperature inferred from a fusion product spectrum. In OMEGA cryogenic implosions, measurement of Te(t) can be used to investigate effects related to time-resolved hot-spot energy balance. The proposed diagnostic utilizes five fast-rise (∼15 ps) scintillator channels with distinct x-ray filtering. Titanium and stepped aluminum filtering were chosen to maximize detector sensitivity in the 10 keV–20 keV range, as it has been shown that these x rays have similar density and temperature weighting to the emitted deuterium–tritium fusion neutrons. Initial data collected using a prototype nosecone on the existing neutron temporal diagnostic demonstrate the validity of this diagnostic technique. The proposed system will be capable of measuring spatially integrated Te(t) with 20 ps time resolution and <10% uncertainty at peak emission in cryogenic DT implosions. [ABSTRACT FROM AUTHOR]

Published

2021

4. Transient magnetic field diffusion considerations relevant to magnetically assisted indirect drive inertial confinement fusion.

Author

Moody, J. D., Johnson, A., Javedani, J., Carroll, E., Fry, J., Kozioziemski, B., Kucheyev, S. O., Logan, B. G., Pollock, B. B., Sio, H., Strozzi, D., Stygar, W. A., Tang, V., and Winters, S.

Subjects

INERTIAL confinement fusion, MAGNETIC fields, DIFFUSION, BLACKBODY radiation, MAGNETICS, DEUTERIUM, TRITIUM

Abstract

Application of a magnetic field to an indirect drive inertial confinement fusion target requires diffusion of the field through the high-Z and electrically conducting Hohlraum. The onset of the external field generates eddy currents in the Hohlraum wall that result in (1) a reduction of the peak field at the capsule, (2) heating of the Hohlraum wall through Ohmic dissipation, and (3) wall movement due to the inward force from the eddy current interacting with the field. Heating of the wall causes an increase in blackbody radiation which can preheat the capsule and frozen deuterium–tritium fuel, while wall motion leads to potential misalignment of the lasers at the Hohlraum wall. Limiting these detrimental effects sets requirements on the tolerable magnitude of each effect. We present a nonlinear model for B-field diffusion through an infinitely long thin-walled cylinder with a temperature dependent resistivity, to show that a 15 lm thick wall of pure gold fails to meet these requirements. A new Hohlraum material made from an alloy of Au and Ta has a measured resistivity of > 60 times that of Au and is shown with the nonlinear model to meet the requirements for magnetization. We compare the nonlinear model to simulations of the actual Hohlraum target using a finite element code which includes temperature-dependent Hohlraum resistivity. [ABSTRACT FROM AUTHOR]

Published

2020

5. A compact neutron spectrometer for characterizing inertial confinement fusion implosions at OMEGA and the NIF.

Author

Zylstra, A. B., Johnson, M. Gatu, Frenje, J. A., Séguin, F. H., Rinderknecht, H. G., Rosenberg, M. J., Sio, H. W., Li, C. K., Petrasso, R. D., McCluskey, M., Mastrosimone, D., Glebov, V. Yu., Forrest, C., Stoeckl, C., and Sangster, T. C.

Subjects

NEUTRON spectrometers, DEUTERIUM, TRITIUM, PROTON measurements, FUEL, NEUTRON temperature

Abstract

A compact spectrometer for measurements of the primary deuterium-tritium neutron spectrum has been designed and implemented on the OMEGA laser facility [T. Boehly et al., Opt. Commun. 133, 495 (1997)]. This instrument uses the recoil spectrometry technique, where neutrons produced in an implosion elastically scatter protons in a plastic foil, which are subsequently detected by a proton spectrometer. This diagnostic is currently capable of measuring the yield to ~±10% accuracy, and mean neutron energy to ~±50 keV precision. As these compact spectrometers can be readily placed at several locations around an implosion, effects of residual fuel bulk flows during burn can be measured. Future improvements to reduce the neutron energy uncertainty to ±15-20 keV are discussed, which will enable measurements of fuel velocities to an accuracy of ~±25-40 km/s. [ABSTRACT FROM AUTHOR]

Published

2014