New Journal of Physics (Jan 2019)

Transverse structure and energy deposition by a subTW femtosecond laser in air: from single filament to superfilament

  • D Pushkarev,
  • E Mitina,
  • D Shipilo,
  • N Panov,
  • D Uryupina,
  • A Ushakov,
  • R Volkov,
  • A Karabutov,
  • I Babushkin,
  • A Demircan,
  • U Morgner,
  • O Kosareva,
  • A Savel’ev

DOI
https://doi.org/10.1088/1367-2630/ab043f
Journal volume & issue
Vol. 21, no. 3
p. 033027

Abstract

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We traced experimentally transition from a single air filament to the superfilament under action of powerful loosely focused (NA ∼ 0.0021) femtosecond beam. Two regimes were exploited with multifilament formation by artificial amplitude or intrinsic amplitude/phase front modulation of the beam having 10–60 critical powers P _cr . Transverse spatial structure and energy density in the filament were studied using wideband acoustic detection and beam mode imaging single shot techniques at different distances along the optical path. We showed that with intrinsic front modulation a single extremely long ionized channel is formed provided peak power P of the initial beam does not exceed 20 P _cr . Its volumetric energy density is ∼1.5–3 times higher than in the single filament, while linear energy density is almost 10 times higher. Artificial amplitude modulation leads to formation of either a single long filament or two closely spaced filaments at the same initial conditions. Maximal volumetric energy density was the same in both cases and slightly less than without this modulation. A few closely spaced filaments are generated at higher peak powers P with volumetric and linear energy densities experiencing fast nonlinear increase with P . Highest linear energy density achieved was 600 μ J cm ^−1 , i.e. almost 100 times higher than that of the single filament with increase in energy 10 times only. The volumetric energy density also increases by a factor of 10 to ∼800 mJ cm ^−3 proving huge increase in intensity and electron density that is characteristic feature of the superfilamentation. These findings were supported by the numerical simulations based on the Forward Maxwell equation with resolved driver of the field that showed superfilament splitting and confirmed energy densities estimated from the experimental data.

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