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Efficient laser wakefield accelerator in pump depletion dominated bubble regime.

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High-energy, few-cycle laser pulses can drive wakefield acceleration, transferring significant energy to electrons. This method shows promise for generating high-charge electron beams and particle sources.

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Area of Science:

  • Plasma Physics
  • Laser-driven Particle Acceleration

Background:

  • Recent advancements in postcompression techniques have enabled the generation of few-cycle joule-class laser pulses.
  • These pulses represent a significant leap in laser technology, reaching 100 TW-class power at a 10 Hz repetition rate.

Purpose of the Study:

  • To investigate the potential of wakefield acceleration driven by these advanced few-cycle joule-class laser pulses.
  • To analyze the energy transfer efficiency and electron beam characteristics in this novel acceleration regime.

Main Methods:

  • Numerical modeling was employed to simulate the interaction of few-cycle joule-class laser pulses with plasma.
  • The simulations focused on analyzing energy transfer, electron acceleration, and wakefield dynamics.

Main Results:

  • Numerical modeling predicts up to 50% laser pulse energy transfer to electrons exceeding 15 MeV.
  • High electron charges, in the nanocoulomb range, are predicted for electrons accelerated to hundreds of MeV.
  • Rapid laser energy depletion drives a strong, cavitated wakefield, leading to massive self-injection.

Conclusions:

  • The explored regime of wakefield acceleration with few-cycle joule-class laser pulses is highly efficient.
  • This approach is suitable for developing advanced Bremsstrahlung emitters and tertiary particle generators, including neutron sources via photonuclear reactions.