AIP Advances (Mar 2021)

Micro-optics for ultra-intense lasers

  • H. Habara,
  • Amit D. Lad,
  • R. Nagami,
  • Prashant Kumar Singh,
  • Gourab Chatterjee,
  • Amitava Adak,
  • Malay Dalui,
  • J. Jha,
  • P. Brijesh,
  • Y. Mishima,
  • K. Nagai,
  • H. Sakagami,
  • Sheroy Tata,
  • T. Madhu Trivikram,
  • M. Krishnamurthy,
  • K. A. Tanaka,
  • G. Ravindra Kumar

DOI
https://doi.org/10.1063/5.0038023
Journal volume & issue
Vol. 11, no. 3
pp. 035214 – 035214-7

Abstract

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Table-top, femtosecond lasers provide the highest light intensities capable of extreme excitation of matter. A key challenge, however, is the efficient coupling of light to matter, a goal addressed by target structuring and laser pulse-shaping. Nanostructured surfaces enhance coupling but require “high contrast” (e.g., for modern ultrahigh intensity lasers, the peak to picosecond pedestal intensity ratio >1012) pulses to preserve target integrity. Here, we demonstrate a foam target that can efficiently absorb a common, low contrast 105 (in picosecond) laser at an intensity of 5 × 1018 W/cm2, giving ∼20 times enhanced relativistic hot electron flux. In addition, such foam target induced “micro-optic” function is analogous to the miniature plasma-parabolic mirror. The simplicity of the target—basically a structure with voids having a diameter of the order of a light wavelength—and the efficacy of these micro-sized voids under low contrast illumination can boost the scope of high intensity lasers for basic science and for table-top sources of high energy particles and ignition of laser fusion targets.