Characterization of time resolved, buried layer plasmas produced by ultrashort laser pulses

We report on the characterization of plasmas produced by ultrashort laser i rradiation of 500 Angstrom thick layers of NaF buried at varying depths in plastic to reduce plasma gradients. The targets are irradiated with 130 fs, approximate to 170 mJ laser pulses (lambda = 400 nm) at an intensity of ap proximate to 2 x 10(18) W cm(-2). The data are spectrally and temporally re solved, with resolutions of lambda/Delta lambda approximate to 1000 and gre ater than or similar to 500 fs, respectively. We use X-ray emission spectro scopy to assess the electron density, N-e, and temperature, T-e, in the pla sma. The density is measured from Stark broadened line profiles of the He-l ike 1 S-1-3 P-1, He-beta, and H-like Ly(beta) lines of Na, while the temper ature is determined from the intensity ratio of Na He-beta to Ly(beta), and also from the dielectronic satellites to these lines. We find peak densiti es and temperatures of greater than or similar to 10(23) cm(-3) and approxi mate to 400 eV, respectively, at 2-4 ps after the laser pulse. The plasma c onditions plateau near these values for 5 ps after that. Atomic data for th e kinetics simulations are generated with the HULLAC suite of codes. The St ark broadened line profiles, with full accounting of satellite transitions, are computed with the TOTAL code. Self-absorption effects are included alo ng the observation line of sight using the radiation transport code CRETIN. Steady-state, non-LTE equilibrium plasma conditions are demonstrated sugge sting that buried-layer experiments can be used as a test bed to study equa tion of state and opacity properties in hot, near-solid density matter. (C) 2001 Elsevier Science Ltd. All rights reserved.