LLE Review 90

Review 90


This volume of the LLE Review, covering January to March 2002, features "First Results from Cryogenic Target Implosions on OMEGA," which describes initial results from direct-drive spherical cryogenic target implosions on the 60-beam OMEGA laser system. These experiments are part of the scientific base leading to direct-drive ignition implosions planned for the National Ignition Facility (NIF). Results shown include neutron yield, secondary-neutron and proton yields, the time of peak neutron emission, and both time-integrated and time-resolved x-ray images of the imploding core. The experimental values are compared with 1-D numerical simulations. The target with an ice-layer nonuniformity of σrms = 9 microns showed 30% of the 1-D predicted neutron yield. These initial results are encouraging for future cryogenic implosions on OMEGA and the NIF.

Additional highlights of research in this issue include the following:

  • Experiments performed on OMEGA as part of the Stockpile Stewardship Program, which measure the equation of state of carbonized resorcinol foam, a porous material, have been modeled. Using the impedance -matching method, the foam Hugoniot was calculated from the well-know equation of state of aluminum and from measured shock speeds over the range of 100 kbar to 2 Mbar.
  • Drive lasers, with know, single-mode modulations, produce nonuniform shocks that propagate into CH targets. An optical probe beam is used to measure the arrival of these modulated shocks at various surfaces in the target. Experiments at moderate laser intensities (less than or approximately equal to 1013 W/cm2) exhibit behavior that is predicted by hydrocodes and simple scaling laws. This technique may be used to observe various dynamic effects in laser-produced plasmas and shock-wave propagation.
  • The time dependence of electron thermal flux inhibition in direct-drive laser implosions has been calculated. The nonlocal electron thermal conduction (in direct-drive CH target implosions driven with square pulses) calculated by one-dimensional Fokker-Planck solver has been combined with the hydrodynamic code. The results show that the electron thermal flux inhibition at the critical surface is time dependent, confirming that a larger flux limiter ms be used for shorter-duration pulses. Also, the growth of the Rayleigh-Taylor instability for short-wavelength perturbations is shown to be smaller due to the longer density scale length.
  • Precision spectral sculpting of broadband FM pulses amplified in a narrowband medium has been demonstrated. Amplification of broadband frequency-modulated (FM) pulses in high-efficiency materials such as Yb+3:SFAP results in significant gain narrowing, leading to reduced on-target bandwidths for beam smoothing and to FM-to-AM conversion. These effects were compensated for by applying precision spectral sculpting, with both amplitude and phase shaping, before amplifying the broadband FM pulses in narrowband gain media. The spectral sculpting, for centerline small-signal gains of 104, produced amplified pulses that have both sufficient bandwidths for on-target beam smoothing and temporal profiles that have not potentially damaging amplitude modulation.
  • Polymer cholesteric liquid crystal flakes suspended in a fluid with non-negligible conductivity can exhibit motion in the presence of an ac electric field. The platelets have a strong selective reflection, which is diminished or extinguished as the flakes move. Flake motion was seen within a specific frequency bandwidth in an electric field as low as 5 mVrms/mm.
  • The response time of a novel, freestanding LT-GaAs photoconductive switch has been measured. The switch was formed by patterning a 1-mm-thick layer of a single-crystal LT-GaAs into a 5-micron by 15-micron bar. The bar was separated from its GaAs substrate and placed across a gold coplanar transmission line deposited on a Si wafer. The switch was excited with 110-fs-wide optical pulses, and its photoresponse was measured with an elecro-optic sampling system. Using 810-optical radiation, 470-fs-wide electrical transients (640-GHz bandwidth) were recorded.

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