Pulse shaping and energy storage capabilities of angularly multiplexed KrF laser fusion drivers Available to Purchase

This paper describes a rep-rated multibeam KrF laser driver design for the $500kJ$ Inertial Fusion test Facility (FTF) recently proposed by NRL, then models its optical pulse shaping capabilities using the ORESTES laser kinetics code. It describes a stable and reliable iteration technique for calculating the required precompensated input pulse shape that will achieve the desired output shape, even when the amplifiers are heavily saturated. It also describes how this precompensation technique could be experimentally implemented in real time on a reprated laser system. The simulations show that this multibeam system can achieve a high fidelity pulse shaping capability, even for a high gain shock ignition pulse whose final spike requires output intensities much higher than the $∼4MW∕cm2$ saturation levels associated with quasi-cw operation; i.e., they show that KrF can act as a storage medium even for pulsewidths of $∼1ns$⁠. For the chosen pulse, which gives a predicted fusion energy gain of $∼120$⁠, the simulations predict the FTF can deliver a total on-target energy of $428kJ$⁠, a peak spike power of $385TW$⁠, and amplified spontaneous emission prepulse contrast ratios $IASE∕I<3×10−7$ in intensity and $FASE∕F<1.5×10−5$ in fluence. Finally, the paper proposes a front-end pulse shaping technique that combines an optical Kerr gate with cw $248nm$ light and a $1μm$ control beam shaped by advanced fiber optic technology, such as the one used in the National Ignition Facility (NIF) laser.