A. Moreau scite author profile

We report a significant enhancement in both the energy and the flux of relativistic electrons accelerated by ultra-intense laser pulse irradiation (>1×10 21 W cm −2 ) of near solid density aligned CD 2 nanowire arrays in comparison to those from solid CD 2 foils irradiated with the same laser pulses. Ultrahigh contrast femtosecond laser pulses penetrate deep into the nanowire array creating a large interaction volume. Detailed three dimensional relativistic particle-in-cell simulations show that electrons originating anywhere along the nanowire length are first driven towards the laser to reach a lower density plasma region near the tip of the nanowires, where they are accelerated to the highest energies. Electrons that reach the lower density plasma experience direct laser acceleration up to the dephasing length, where they outrun the laser pulse. This yields an electron beam characterized by a 3× higher electron temperature and an integrated flux 22.4× larger respect to foil targets. Additionally, the generation of>1 MeV photons were observed to increase up to 4.5×.

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Extreme ionization of heavy atoms in solid-density plasmas by relativistic second-harmonic laser pulses

Hollinger

Wang

et al. 2020

Nat. Photonics

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Vacuum laser acceleration of super-ponderomotive electrons using relativistic transparency injection

Singh

Huang

et al. 2022

Nat Commun

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Intense lasers can accelerate electrons to very high energy over a short distance. Such compact accelerators have several potential applications including fast ignition, high energy physics, and radiography. Among the various schemes of laser-based electron acceleration, vacuum laser acceleration has the merits of super-high acceleration gradient and great simplicity. Yet its realization has been difficult because injecting free electrons into the fast-oscillating laser field is not trivial. Here we demonstrate free-electron injection and subsequent vacuum laser acceleration of electrons up to 20 MeV using the relativistic transparency effect. When a high-contrast intense laser drives a thin solid foil, electrons from the dense opaque plasma are first accelerated to near-light speed by the standing laser wave in front of the solid foil and subsequently injected into the transmitted laser field as the opaque plasma becomes relativistically transparent. It is possible to further optimize the electron injection/acceleration by manipulating the laser polarization, incident angle, and temporal pulse shaping. Our result also sheds light on the fundamental relativistic transparency process, crucial for producing secondary particle and light sources.

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Solid-Density Ion Temperature from Redshifted and Double-Peaked Stark Line Shapes

et al. 2021

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Ablating Ion Velocity Distributions in Short-Pulse-Heated Solids via X-Ray Doppler Shifts

et al. 2022

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A. Moreau

Enhanced electron acceleration in aligned nanowire arrays irradiated at highly relativistic intensities

Extreme ionization of heavy atoms in solid-density plasmas by relativistic second-harmonic laser pulses

Vacuum laser acceleration of super-ponderomotive electrons using relativistic transparency injection

Solid-Density Ion Temperature from Redshifted and Double-Peaked Stark Line Shapes

Ablating Ion Velocity Distributions in Short-Pulse-Heated Solids via X-Ray Doppler Shifts

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