Proceedings Article | 28 May 2004
Phillip Arnold, Craig Ollis, Andrew Hinz, Calvin Robb, Keith Primdahl, Jayson Watson, Michael O'Brien, William Funkhouser, Peter Biltoft, Randy Shelton, William Tapley, William DeHope
KEYWORDS: National Ignition Facility, Plasma, Crystals, Electrodes, Optical amplifiers, Control systems, Polarizers, Pulse generators, Polarization, Laser crystals
Large aperture Plasma Electrode Pockels Cells (PEPCs) are an enabling technology in the National Ignition Facility
(NIF) at the Lawrence Livermore National Laboratory. The Pockels cells allow the NIF laser to take advantage of multipass
main amplifier architecture, thus reducing costs and physical size of the facility. Each Pockels cell comprises four
40-cm x 40-cm apertures arranged in a 4x1 array. The combination of the Pockels cell and a thin-film polarizer, also
configured in a 4x1 array, forms an optical switch that is key to achieving the required multi-pass operation.
The operation of the PEPC is a follows: Before the arrival of the laser pulse, optically transparent, low-density helium
plasmas are initiated to serve as electrodes for the KDP crystals mounted in the Pockels cell. During beam propagation
through the main laser cavity a longitudinal electric field is impressed on the electro-optic crystals. The polarization of
the propagating beams is rotated by 90° on each of two passes, thereby allowing the beam to be trapped in the main laser
amplifier cavity for a total of four passes before being switched out into the cavity spatial filter.
The physics aspects of the PEPC are well documented. Consequently, this paper will emphasize the PEPC subsystem in
the context of its role and relevance within the broader NIF laser system, provide a view of the complexity of the
subsystem and give an overview of PEPC's interactions with other elements of NIF, including interfaces to the Beamline
Infrastructure, the NIF Timing Subsystem, and the Integrated Computer Control System (ICCS); along with dependence
on the Optics Production, Transport and Handling (T&H), and Assembly, Integration and Refurbishment (AIR) and
Operations organizations. Further, we will discuss implementation details related to the functional blocks and individual
components that comprise PEPC, with particular emphasis on the unique constraints placed on the elements and the
attendant engineering solutions. Finally, we describe performance, fabrication and assembly requirements unique to
PEPC and the various considerations necessary for successfully commissioning and operation of each PEPC unit. These
considerations include, but are not limited to, materials choices, materials preparation and processing (especially
cleanliness), inspection, pre- and post-assembly testing.
