Your search keyword '"Sjue, S. K."' showing total 5 results

1. Compaction model validation under non-planar shock wave loading conditions.

Author

Voorhees, T. J., Freeman, M. S., Rousculp, C. L., Fredenburg, D. A., Carney, T. C., Bradley, J. T., Donovan, P. M., Fierro, F., Griego, J. R., Lamar, J. C., Mariam, F. G., Neukirch, L. P., Oro, D. M., Patten, A. R., Randolph, R. B., Reass, W. A., Reinovsky, R. E., Saunders, A., Sjue, S. K., and Tang, Z.

Subjects

MODEL validation, COMPACTING, RADIOGRAPHY

Abstract

Three continuum compaction models are calibrated to planar impact data for CeO2 powder and used to predict the shock compaction behavior of CeO2 powder under cylindrically converging shock wave loading. All experiments and computations are performed on powder compacts with an initial pressed density of 4.0 g/cm3 (56% TMD). A magnetically-driven, cylindrically-converging shock compaction experiment is computationally designed using the calibrated compaction models in the multi-physics code FLAG. Magnetohydrodynamic (MHD) calculations of impact conditions are performed using a calibrated circuit model in FLAG. The first cylindrical shock compaction experiment is executed using the mobile pulsed power driver PHELIX. In situ areal density measurements of the CeO2 target assembly are performed during the compaction event with proton radiography. Calculations of the late time compaction response of the CeO2 powder under PHELIX compression are greater than 90% accurate using the P-α compaction models calibrated under planar loading. [ABSTRACT FROM AUTHOR]

Published

2020

2. High order magnetic optics for high dynamic range proton radiography at a kinetic energy of 800 MeV.

Author

Sjue, S. K. L., Mariam, F. G., Merrill, F. E., Morris, C. L., and Saunders, A.

Subjects

*KINETIC energy, *PROTONS, *RADIOGRAPHY, *PULSED power systems, *SCATTERING (Physics), *QUADRUPOLES, *ELECTROMAGNETS

Abstract

Flash radiography with 800 MeV kinetic energy protons at Los Alamos National Laboratory is an important experimental tool for investigations of dynamic material behavior driven by high explosives or pulsed power. The extraction of quantitative information about density fields in a dynamic experiment from proton generated images requires a high fidelity model of the proton imaging process. It is shown that accurate calculations of the transmission through the magnetic lens system require terms beyond second order for protons far from the tune energy. The approach used integrates the correlated multiple Coulomb scattering distribution simultaneously over the collimator and the image plane. Comparison with a series of static calibration images demonstrates the model's accurate reproduction of both the transmission and blur over a wide range of tune energies in an inverse identity lens that consists of four quadrupole electromagnets. [ABSTRACT FROM AUTHOR]

Published

2016

3. Radial distribution of charged particles in a magnetic field.

Author

Sjue, S. K. L., Broussard, L. J., Makela, M., McGaughey, P. L., Young, A. R., and Zeck, B. A.

Subjects

*MAGNETIC fields, *DETECTORS, *RADIAL distribution function, *DISTRIBUTION (Probability theory), *SOLENOIDS

Abstract

The radial spread of charged particles emitted from a point source in a magnetic field is a potential source of systematic error for any experiment where magnetic fields guide charged particles to detectors with finite size. Assuming uniform probability as a function of the phase along the particle's helical trajectory, an analytic solution for the radial probability distribution function follows which applies to experiments in which particles are generated throughout a volume that spans a sufficient length along the axis of a homogeneous magnetic field. This approach leads to the same result as a different derivation given by Dubbers et al., Nucl. Instrum. Methods Phys. Res., Sect. A 763, 112-119 (2014). But the constant phase approximation does not strictly apply to finite source volumes or fixed positions, which lead to local maxima in the radial distribution of emitted particles at the plane of the detector. A simple method is given to calculate such distributions, then the effect is demonstrated with data from a 207Bi electron-conversion source in the superconducting solenoid magnet spectrometer of the Ultracold Neutron facility at the Los Alamos Neutron Science Center. Implications for neutron beta decay spectroscopy are discussed. [ABSTRACT FROM AUTHOR]

Published

2015

4. Mass of the lowest T = 2 state of 32S.

Author

Triambak, S., García, A., Adelberger, E. G., Hodges, G. J. P., Swanson, H. E., Hoedl, S. A., Sjue, S. K. L., and Sallaska, A. L.

Subjects

SULFUR, CHEMICAL reactions, CHEMICAL processes, PHYSICS, NUCLEAR physics

Abstract

We determined the mass of the lowest T = 2 state in 32S with unprecedented accuracy and precision (ΔM/M ≈ 10-5). The state was produced via the 31P(p,γ) reaction and the energies of the de-excitation γ rays measured with high accuracy. This, together, with a recent measurement of the mass of 32Ar provides a stringent test of the Isobaric Multiplet Mass Equation (IMME) for the A = 32 multiplet. A significant violation of the IMME is observed. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2006

5. A new method for measuring the neutron lifetime using an in situ neutron detector.

Author

Morris CL, Adamek ER, Broussard LJ, Callahan NB, Clayton SM, Cude-Woods C, Currie SA, Ding X, Fox W, Hickerson KP, Hoffbauer MA, Holley AT, Komives A, Liu CY, Makela M, Pattie RW Jr, Ramsey J, Salvat DJ, Saunders A, Seestrom SJ, Sharapov EI, Sjue SK, Tang Z, Vanderwerp J, Vogelaar B, Walstrom PL, Wang Z, Wei W, Wexler JW, Womack TL, Young AR, and Zeck BA

Abstract

In this paper, we describe a new method for measuring surviving neutrons in neutron lifetime measurements using bottled ultracold neutrons (UCN), which provides better characterization of systematic uncertainties and enables higher precision than previous measurement techniques. An active detector that can be lowered into the trap has been used to measure the neutron distribution as a function of height and measure the influence of marginally trapped UCN on the neutron lifetime measurement. In addition, measurements have demonstrated phase-space evolution and its effect on the lifetime measurement.

Published

2017