Frequency Conversion Theory in Support of the National Ignition Facility Peter W. Milonni Various target simulations and experiments indicate that the most desirable laser wavelengths for inertial confinement fusion lie near 0.3 mm, whereas the high-energy glass laser systems designed for the National Ignition Facility (NIF) emit near 1.05 mm. A crucial part of NIF therefore centers around the frequency tripling of the 1.05 mm radiation. The NIF baseline design involves two KDP (potassium dihydrogen phosphate) crystals for this purpose. Laser radiation incident on the first crystal is doubled in frequency via the nonlinear susceptibility of KDP, and in the second crystal the residual fundamental mixes with the second harmonic via this same nonlinearity to generate the desired third harmonic (Figure 1). This design was based on simplified theoretical analyses performed at several laboratories, and on experimental confirmations that third-harmonic conversion efficiencies on the order of 70% could in fact be realized. However, the analyses were based on highly simplied assumptions such as perfect plane-wave and monochromatic fields, and the experiments were somewhat artificial in that they were designed to meet these idealized conditions as closely as possible. NIF fields will have both phase and intensity variations in space and in time, and our work over the past three years has focused on more realistic simulations of experiments at Lawrence Livermore National Laboratory (LLNL), as well as the design of more efficient frequency conversion schemes under conditions of practical interest for NIF. We have developed the theory and computer codes accomodating arbitrary spatial and temporal variations of the fundamental and harmonic fields. Comparison of the code predictions with measured LLNL harmonic conversion efficiencies showed excellent agreement except at the highest field intensities, where the predictions for frequency tripling efficiencies were typically 10-20% higher than was measured. However, we found that the addition of small phase ripples across the incident fundamental wavefront had the effect of lowering the high-intensity conversion efficiencies while leaving the lower-intensity predictions essentially unaltered (Figure 2). Interferometric analyses of the KDP crystals showed that machining and polishing "grooves" on the crystal surfaces were of approximately the amplitude and period required to translate effectively into the sort of phase ripples we had postulated. Subsequent experiments at LLNL introduced deliberate phase ripples on the incident wavefront and corroborated the essential predictions of our code and also an approximate perturbation-theoretic analysis of phase ripples. We have suggested three- and four-crystal designs in order to efficiently triple fields with the temporal intensity profile believed to be most propitious for NIF, as well as fields with large bandwidth produced by phase modulation. The latter is particularly relevant for direct-drive ICF. Three-crystal experiments at LLNL have produced conversion efficiencies in agreement with theoretical expectations, and large-bandwidth experiments are expected to be undertaken in the near future. Figure 1: Type I/type II scheme for third-harmonic generation. o and e denote polarization directions for ordinary and extraordinary waves. Figure 2: Comparison of theory to experimental data points (D). The dashed curve is the theoretical prediction for the third-harmonic conversion efficiency versus input intensity to the doubling crystal, assuming a uniform phase profile, whereas the solid curve includes small phase ripples on the input field.