Speaker
Description
Intense lasers enable a range of schemes for generating high-energy particle beams in university-scale laboratories. In direct laser acceleration (DLA), the leading edge of the laser pulse ionizes the target material, forming a positively charged plasma channel that traps and accelerates electrons. DLA offers exceptional conversion efficiency — often exceeding 20% — making it highly suitable for driving secondary radiation sources. This talk reviews recent advances aimed at pushing the efficiency and applicability of DLA for X-ray and neutron generation.
I will present experimental and numerical studies showing how DLA performance can be enhanced by tailoring the target’s atomic number to sustain electron injection, and by employing flying-focus pulses to stabilize the plasma channel and extend the acceleration length.
Building on these developments, I will demonstrate how high accumulated neutron yields were achieved via bremsstrahlung from MeV electron beams in high-repetition-rate laser shots, and how a bright Compton X-ray source can be realized using counter-propagating pulses in a near-critical plasma plume.
The talk will conclude with projections for scaling these approaches to the multi-petawatt regime, where improved overlap between electron energies and neutron production cross-sections is expected to enable non-destructive material analysis and support industrial applications.
Cohen, I., et. al, Undepleted direct laser acceleration, Sci. Adv.10,eadk1947(2024).
Cohen, I., et. al, Multi-scale analytical description of an expanding plasma slab, Physics of Plasmas 31.1 (2024).
Meir, T., et. al, Plasma-guided Compton source, Physical Review Applied, 22(4), p.044004 (2024).
Cohen, I., et. al, Accumulated laser-photoneutron generation, The European Physical Journal Plus, 139(7), pp.1-7(2024).
