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Paper detail

Plasma surface dynamics and smoothing in the relativistic few-cycle regime

In laser-plasma interactions it is widely accepted that a non-uniform interaction surface will invariably seed hydrodynamic instabilities and a growth in the amplitude of the initial modulation. Recent experimental results [Dromey, Nat. Phys. 2009] have demonstrated that there must be target smoothing in femtosecond timescale relativistic interactions, contrary to prevailing expectation. In this paper we develop a theoretical description of the physical process that underlies this novel phenomena. We show that the surface dynamics in the few-cycle relativistic regime is dominated by the coherent electron motion resulting in a smoothing of the electron surface. This stabilization of plasma surfaces is unique in laser-plasma interactions and demonstrates that dynamics in the few-cycle regime differ fundamentally from the longer pulse regimes. This has important consequences for applications such as radiation pressure acceleration of protons and ions and harmonic generation from relativistically oscillating surfaces.

preprint2010arXivOpen access
S. G. RykovanovH. RuhlJ. Meyer-ter-VehnR. HoerleinB. DromeyM. ZepfG. D. Tsakiris
physics.plasm-phphysics.optics
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S. G. RykovanovH. RuhlJ. Meyer-ter-VehnR. HoerleinB. DromeyM. ZepfG. D. Tsakiris

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