Your search keyword '"Samuel A. Letzring"' showing total 3 results

1. Direct‐drive laser‐fusion experiments with the OMEGA, 60‐beam, >40 kJ, ultraviolet laser system

Author

S. D. Jacobs, S. Skupsky, R. L. Keck, R. W. Short, C. P. Verdon, S. Swales, A. Babushkin, Mark D. Skeldon, R. E. Bahr, M. D. Wittman, Ansgar W. Schmid, S. J. Loucks, Semyon Papernov, R. L. McCrory, William R. Donaldson, Robert Kremens, P. W. McKenty, J. A. Delettrez, John H. Kelly, K. Kearney, S. F. B. Morse, D. J. Lonobile, Paul A. Jaanimagi, W. Seka, D. K. Bradley, S. A. Kumpan, J. M. Soures, Andrey V. Okishev, J. P. Knauer, D. L. Brown, Milton J. Shoup, T. R. Boehly, L. D. Lund, Douglas J. Smith, Terrance J. Kessler, Robert Boni, Reuben Epstein, R. S. Craxton, F. J. Marshall, D. D. Meyerhofer, G. Pien, Samuel A. Letzring, and B. Yaakobi

Subjects

Physics, Thermonuclear fusion, business.industry, Implosion, Plasma, Condensed Matter Physics, Laser, law.invention, Optics, law, Neutron, business, National Ignition Facility, Inertial confinement fusion, Beam (structure)

Abstract

OMEGA, a 60‐beam, 351 nm, Nd:glass laser with an on‐target energy capability of more than 40 kJ, is a flexible facility that can be used for both direct‐ and indirect‐drive targets and is designed to ultimately achieve irradiation uniformity of 1% on direct‐drive capsules with shaped laser pulses (dynamic range ≳400:1). The OMEGA program for the next five years includes plasma physics experiments to investigate laser–matter interaction physics at temperatures, densities, and scale lengths approaching those of direct‐drive capsules designed for the 1.8 MJ National Ignition Facility (NIF); experiments to characterize and mitigate the deleterious effects of hydrodynamic instabilities; and implosion experiments with capsules that are hydrodynamically equivalent to high‐gain, direct‐drive capsules. Details are presented of the OMEGA direct‐drive experimental program and initial data from direct‐drive implosion experiments that have achieved the highest thermonuclear yield (1014 DT neutrons) and yield efficienc...

Published

1996

2. Increased efficiency of short-pulse laser-generated proton beams from novel flat-top cone targets

Author

N. Renard-LeGalloudec, J. Rassuchine, Steven Malekos, Randall P. Johnson, Thomas E. Cowan, Donald C. Gautier, Bjorn Hegelich, F. Nürnberg, Brian J. Albright, Yasuhiko Sentoku, Kirk Flippo, Grant Korgan, Markus Roth, Juan C. Fernandez, John Kline, Michael S. Bakeman, Sandrine Gaillard, Marius Schollmeier, Emmanuel d'Humières, K. Harres, Joshua J. Adams, Samuel A. Letzring, and T. Shimada

Subjects

Physics, Thermonuclear fusion, Proton, business.industry, Condensed Matter Physics, IGNITOR, Laser, Ion, law.invention, Nuclear physics, Ignition system, Optics, Physics::Plasma Physics, law, business, Scaling, Beam (structure)

Abstract

Ion-driven fast ignition (IFI) may have significant advantages over electron-driven FI due to the potentially large reduction in the amount of energy required for the ignition beam and the laser driver. Recent experiments at the Los Alamos National Laboratory’s Trident facility employing novel Au flat-top cone targets have produced a fourfold increase in laser-energy to ion-energy efficiency, a 13-fold increase in the number of ions above 10MeV, and a few times increase in the maximum ion energy compared to Au flat-foil targets. Compared to recently published scaling laws, these gains are even greater. If the efficiency scales with intensity in accordance to flat-foil scaling, then, with little modification, these targets can be used to generate the pulse of ions needed to ignite thermonuclear fusion in the fast ignitor scheme. A proton energy of at least 30MeV was measured from the flat-top cone targets, and particle-in-cell (PIC) simulations show that the maximum cutoff energy may be as high as 40–45MeV...

Published

2008

3. Spectral properties of laser-accelerated mid-Z MeV∕u ion beams

Author

D. Habs, Andreas Kemp, E. Brambrink, Patrick Audebert, C. Gautier, Thomas E. Cowan, Abel Blazevic, Klaus Witte, Bjorn Hegelich, Markus Roth, Brian J. Albright, Jörg Schreiber, Ulrich Schramm, J. C. Gauthier, M. Geissel, Randall P. Johnson, Juan C. Fernandez, J. Cobble, Samuel A. Letzring, Stefan Karsch, and Julien Fuchs

Subjects

Physics, Proton, chemistry.chemical_element, Condensed Matter Physics, Laser, Collimated light, Ion, law.invention, chemistry, law, Physics::Accelerator Physics, Plasma diagnostics, Irradiation, Atomic physics, Beryllium, Nuclear Experiment, Joule heating

Abstract

Collimated jets of beryllium, carbon, oxygen, fluorine, and palladium ions with >1MeV∕nucleon energies are observed from the rear surface of thin foils irradiated with laser intensities of up to 5×1019W∕cm2. The normally dominant proton acceleration is suppressed when the target is subjected to Joule heating to remove hydrogen-bearing contaminant. This inhibits screening effects and permits effective energy transfer to and acceleration of heavier ion species. The influence of remnant protons on the spectral shape of the next highest charge-to-mass ratio species is shown. Particle-in-cell simulations confirming the experimental findings are presented.

Published

2005