Anomalous hot electron generation from two-plasmon decay instability driven by broadband laser pulses with intensity modulations
Abstract
We investigate the hot electrons generated from two-plasmon decay (TPD) instability driven by laser pulses with intensity modulated by a frequency ωm. Our primary focus lies on scenarios where ωm is on the same order of the TPD growth rate γ0 ( ωm γ0), corresponding to moderate laser frequency bandwidths for TPD mitigation. With ωm conveniently modeled by a basic two-color scheme of the laser wave fields in fully-kinetic particle-in-cell simulations, we demonstrate that the energies of TPD modes and hot electrons exhibit intermittent evolution at the frequency ωm, particularly when ωm γ0. With the dynamic TPD behavior, the overall ratio of hot electron energy to the incident laser energy, fhot, changes significantly with ωm. While fhot drops notably with increasing ωm at large ωm limit as expected, it goes anomalously beyond the hot electron energy ratio for a single-frequency incident laser pulse with the same average intensity when ωm falls below a specific threshold frequency ωc. We find this threshold frequency primarily depends on γ0 and the collisional damping rate of plasma waves, with relatively lower sensitivity to the density scale length. We develop a scaling model characterizing the relation of ωc and laser plasma conditions, enabling the potential extention of our findings to more complex and realistic scenarios.
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