Detailed characterization of kHz-rate laser-driven fusion at a thin liquid sheet with a neutron detection suite

We present detailed characterization of laser-driven fusion and neutron production (similar to 10(5)/second) using 8 mJ, 40 fs laser pulses on a thin (<1 mu m) D2O liquid sheet employing a measurement suite. At relativistic intensity (similar to 5x10(18 )W/cm(2)) and high repetition rate (1 kHz), the system produces deuterium-deuterium (D-D) fusion, allowing for consistent neutron generation. Evidence of D-D fusion neutron production is verified by a measurement suite with three independent detection systems: an EJ-309 organic scintillator with pulse-shape discrimination, a He-3 proportional counter and a set of 36 bubble detectors. Time-of-flight analysis of the scintillator data shows the energy of the produced neutrons to be consistent with 2.45 MeV. Particle-in-cell simulations using the WarpX code support significant neutron production from D-D fusion events in the laser-target interaction region. This high-repetition-rate laser-driven neutron source could provide a low-cost, on-demand test bed for radiation hardening and imaging applications.