A five-temperature model for the CO 2 -N2 -He system has been employed to predict the output-power pulse shape from a TEA laser. Theoretical predictions are compared to experimental data for several gas mixtures, cavity configurations, and excitation levels with good agreement. This model should be useful in the evaluation of alternative pumping schemes and in the understanding of CO, TEA laser dynamics when nonlinear media are placed in the optical cavity.
We present an empirical model that describes the experimentally observed laser-induced bulk damage and conditioning behavior in deuterated potassium dihydrogen phosphate (DKDP) crystals. The model expands on an existing nanoabsorber precursor model and the multistep absorption mechanism to include two populations of absorbing defects, one with linear absorption and another with nonlinear absorption. We show that this model connects previously uncorrelated small-beam damage initiation probability data to large-beam damage density measurements over a range of nanosecond pulse widths. In addition, this work predicts the damage behavior of laser-conditioned DKDP.
We have found the local temporal shot-to-shot variation of the NIF high-energy laser system to be relatively constant (~3.4% to 4.2% of the mean fluence). We have developed a statistical model that predicts the maximum fluence distribution any particular location will be exposed to after N independent shots (the so-called max-of-N fluence distribution) using the measured shot-to-shot variance; this method allows for an estimate of maximum optics fluence exposure.
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