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Title: Diagnosing implosion velocity and ablator dynamics at NIF (u)

Abstract

An enhanced understanding of the unique physics probed in a burning NIP capsule is important for both nuclear weapons physics and thermonuclear ignition. In this talk we introduce a new diagnostic idea, designed to measure dynamic aspects of the capsule implosion that are not currently accessible. The current set of diagnostics for the NIF experiments includes reaction history (a time resolved measure of the d + t burn), neutron time-of-flight and spectrometry and spatial imaging of the neutron production and scattering. Although valuable, this abbreviated set of diagnostics cannot determine key dynamical properties of the implosion, such as implosion velocity (v{sub impl}) and ablator thickness. To surpass the present limits of {approx} 10{sup 15} d+t reactions, it will be necessary to increase significantly the implosion energy delivered to the DT fuel by finely tuning the balance between the remaining (imploding) ablator mass and velocity. If too much mass remains, the implosion velocity will be too slow, and the subsecpwnt PdV work will not be sufficient to overcome cooling via conduction and radiation. If too little mass remains, hydrodynamic instabilities will occur, resulting in unpredictable and degraded performance. Detailed calculations suggest the ablator must reach an implosion velocity of 3-4 xmore » 10{sup 7} cm/sec and an areal density of {rho}{Delta}R {approx}200 mg/cm{sup 2} in order to achieve ignition. The authors present a new scheme to measure these important quantities using neutron reactions on the ablator material. During the burn, the ablator is moving relative to the 14.1 MeV d+t neutrons that are traversing the capsule. The resulting neutron-ablator Doppler shift causes a few unique nuclear reactions to become sensitive detectors of the ablator velocity at peak burn time. The 'point-design' capsule at the NIF will be based on a {sup 9}Be ablator, and the {sup 9}Be(n,p){sup 9}Li reaction has an energy threshold of 14.2 MeV, making it the ideal probe. As discussed in detail below, differences in the ablalor velocity lead to significant differences in the rate of {sup 9}Li production. We present techniques for measuring this {sup 9}Li implosion velocity diagnostic at the NIF . The same experimental techniques measuring neutron reactions on the ablator material, will allow us to determine other important dynamical quantities, such as the areal density ({rho}{Delta}R) and approximate thickness ({Delta}R) of the ablator at peak burn.« less

Authors:
 [1];  [1];  [1];  [1];  [1];  [1];  [1]
  1. Los Alamos National Laboratory
Publication Date:
Research Org.:
Los Alamos National Laboratory (LANL), Los Alamos, NM (United States)
Sponsoring Org.:
USDOE
OSTI Identifier:
990774
Report Number(s):
LA-UR-09-04348; LA-UR-09-4348
TRN: US201020%%587
DOE Contract Number:  
AC52-06NA25396
Resource Type:
Conference
Resource Relation:
Conference: Nuclear Explosives Design Physics Conference (NEDPC) ; October 26, 2009 ; Livermore, CA
Country of Publication:
United States
Language:
English
Subject:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY; DESIGN; HYDRODYNAMICS; IGNITION; IMPLOSIONS; NEUTRON REACTIONS; NEUTRONS; NUCLEAR EXPLOSIVES; NUCLEAR REACTIONS; NUCLEAR WEAPONS; PERFORMANCE; PHYSICS; PRODUCTION; SCATTERING; SPECTROSCOPY; THERMONUCLEAR IGNITION; THICKNESS; TUNING; VELOCITY

Citation Formats

Hayes, Anna, Grim, Gary, Jungnam, Jerry, Bradley, Paul, Rundberg, Bob, Wilhelmy, Jerry, and Wilson, Doug. Diagnosing implosion velocity and ablator dynamics at NIF (u). United States: N. p., 2009. Web.
Hayes, Anna, Grim, Gary, Jungnam, Jerry, Bradley, Paul, Rundberg, Bob, Wilhelmy, Jerry, & Wilson, Doug. Diagnosing implosion velocity and ablator dynamics at NIF (u). United States.
Hayes, Anna, Grim, Gary, Jungnam, Jerry, Bradley, Paul, Rundberg, Bob, Wilhelmy, Jerry, and Wilson, Doug. 2009. "Diagnosing implosion velocity and ablator dynamics at NIF (u)". United States. https://www.osti.gov/servlets/purl/990774.
@article{osti_990774,
title = {Diagnosing implosion velocity and ablator dynamics at NIF (u)},
author = {Hayes, Anna and Grim, Gary and Jungnam, Jerry and Bradley, Paul and Rundberg, Bob and Wilhelmy, Jerry and Wilson, Doug},
abstractNote = {An enhanced understanding of the unique physics probed in a burning NIP capsule is important for both nuclear weapons physics and thermonuclear ignition. In this talk we introduce a new diagnostic idea, designed to measure dynamic aspects of the capsule implosion that are not currently accessible. The current set of diagnostics for the NIF experiments includes reaction history (a time resolved measure of the d + t burn), neutron time-of-flight and spectrometry and spatial imaging of the neutron production and scattering. Although valuable, this abbreviated set of diagnostics cannot determine key dynamical properties of the implosion, such as implosion velocity (v{sub impl}) and ablator thickness. To surpass the present limits of {approx} 10{sup 15} d+t reactions, it will be necessary to increase significantly the implosion energy delivered to the DT fuel by finely tuning the balance between the remaining (imploding) ablator mass and velocity. If too much mass remains, the implosion velocity will be too slow, and the subsecpwnt PdV work will not be sufficient to overcome cooling via conduction and radiation. If too little mass remains, hydrodynamic instabilities will occur, resulting in unpredictable and degraded performance. Detailed calculations suggest the ablator must reach an implosion velocity of 3-4 x 10{sup 7} cm/sec and an areal density of {rho}{Delta}R {approx}200 mg/cm{sup 2} in order to achieve ignition. The authors present a new scheme to measure these important quantities using neutron reactions on the ablator material. During the burn, the ablator is moving relative to the 14.1 MeV d+t neutrons that are traversing the capsule. The resulting neutron-ablator Doppler shift causes a few unique nuclear reactions to become sensitive detectors of the ablator velocity at peak burn time. The 'point-design' capsule at the NIF will be based on a {sup 9}Be ablator, and the {sup 9}Be(n,p){sup 9}Li reaction has an energy threshold of 14.2 MeV, making it the ideal probe. As discussed in detail below, differences in the ablalor velocity lead to significant differences in the rate of {sup 9}Li production. We present techniques for measuring this {sup 9}Li implosion velocity diagnostic at the NIF . The same experimental techniques measuring neutron reactions on the ablator material, will allow us to determine other important dynamical quantities, such as the areal density ({rho}{Delta}R) and approximate thickness ({Delta}R) of the ablator at peak burn.},
doi = {},
url = {https://www.osti.gov/biblio/990774}, journal = {},
number = ,
volume = ,
place = {United States},
year = {Thu Jul 09 00:00:00 EDT 2009},
month = {Thu Jul 09 00:00:00 EDT 2009}
}

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