52nd Annual Meeting of the APS Division of Plasma Physics
Volume 55, Number 15
Monday–Friday, November 8–12, 2010;
Chicago, Illinois
Session MR1: Review: Overview of the National Ignition Campaign (NIC)
8:00 AM–9:00 AM,
Wednesday, November 10, 2010
Room: Grand Ballroom CD/EF
Chair: David Meyerhofer, University of Rochester
Abstract ID: BAPS.2010.DPP.MR1.1
Abstract: MR1.00001 : Overview of the National Ignition Campaign (NIC)
8:00 AM–9:00 AM
Preview Abstract
Author:
Edward Moses
(Lawrence Livermore National Laboratory)
The 192-beam National Ignition Facility (NIF) at Lawrence
Livermore National
Laboratory (LLNL) is now operational. NIF has conducted 192-beam
implosion
experiments with energies as high as 1.2 MJ and has also
demonstrated the
unprecedented energy and pulse shaping control required for ignition
experiments.
The successful commissioning of the NIF laser is the first step in
demonstrating inertial confinement fusion (ICF) ignition in the
laboratory.
The NIF ignition program is executed via the National Ignition
Campaign
(NIC)---a partnership between Los Alamos National Laboratory,
Lawrence
Berkeley Laboratory, LLNL, General Atomics, the University of
Rochester
Laboratory for Laser Energetics, Sandia National Laboratories, the
Massachusetts Institute of Technology, and other national and
international
partners.
The NIC relies on a novel integrated experimental and
computational program
to tune the target to the conditions required for indirect-drive
ignition.
This approach breaks the tuning process into four phases. The
first two
phases involve tuning of the hohlraum and capsule to produce the
correct
radiation drive, symmetry, and shock timing conditions. The third
phase
consists of layered cryogenic implosions conducted with a
50{\%}/49{\%}/1{\%} mixture of tritium, hydrogen, and deuterium
(THD)
respectively. The reduced yield from these THD targets allows the
full
diagnostic suite to be employed and the presence of the required
temperature
and fuel areal density to be verified. The final step is DT ignition
implosions with expected gains of 10-20. DT ignition experiments
will be
conducted with Elaser $\sim $1.2 MJ. Laser energies of 1.8 MJ
should be
available for subsequent experiments.
This talk will review the multi-phase tuning approach to the
ignition
effort, including the physics issues associated with the various
steps, and
current and future plans for the NIF ignition program.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.DPP.MR1.1