Post-compression of high-energy, sub-picosecond laser pulses

P. G. Bleotu; J. Wheeler; S. Yu Mironov; V. Ginzburg; M. Masruri; A. Naziru; R. Secareanu; D. Ursescu; F. Perez; J. De Sousa; D. Badarau; E. Veuillot; P. Audebert; E. Khazanov; G. Mourou

doi:10.1017/hpl.2023.10

Post-compression of high-energy, sub-picosecond laser pulses

P. G. Bleotu
, J. Wheeler
, S. Yu Mironov
, V. Ginzburg
, M. Masruri
, A. Naziru
, R. Secareanu
, D. Ursescu
, F. Perez
, J. De Sousa
, D. Badarau
, E. Veuillot
, P. Audebert
, E. Khazanov
, G. Mourou

Sorbonne Université
University of Bucharest
Horia Hulubei National Institute of Physics and Nuclear Engineering
Ecole Polytechnique, IZEST
Independent Researcher
Institute of Applied Physics of the Russian Academy of Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

The post-compression technique based on self-phase modulation of high-energy pulses leads to an increase in achievable peak power and intensity. Typically, the pulses considered in experiments have been less than 100 fs in duration. Here, the method is applied to the ELFIE laser system at the LULI facility, for a pulse of 7 J energy and an initial measured duration of 350 fs. A 5-mm-thick fused silica window and a 2 mm cyclic-olefin polymer were used as optical nonlinear materials. The 9 cm diameter beam was spectrally broadened to a bandwidth corresponding to 124 fs Fourier-limited pulse duration, and then it was partly post-compressed to 200 fs. After measuring the spatial spectra of the beam fluence, a uniform gain factor of 4 increase in the fluctuations over the studied range of frequencies is observed, due to small-scale self-focusing.

Original language	English
Article number	e30
Journal	High Power Laser Science and Engineering
Volume	11
DOIs	https://doi.org/10.1017/hpl.2023.10
Publication status	Published - 16 Feb 2023

Keywords

high-power laser
nonlinear pulse interaction
post-compression
self-phase modulation

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10.1017/hpl.2023.10

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@article{35b1ef7068cc4ed489706fa2f429b542,

title = "Post-compression of high-energy, sub-picosecond laser pulses",

abstract = "The post-compression technique based on self-phase modulation of high-energy pulses leads to an increase in achievable peak power and intensity. Typically, the pulses considered in experiments have been less than 100 fs in duration. Here, the method is applied to the ELFIE laser system at the LULI facility, for a pulse of 7 J energy and an initial measured duration of 350 fs. A 5-mm-thick fused silica window and a 2 mm cyclic-olefin polymer were used as optical nonlinear materials. The 9 cm diameter beam was spectrally broadened to a bandwidth corresponding to 124 fs Fourier-limited pulse duration, and then it was partly post-compressed to 200 fs. After measuring the spatial spectra of the beam fluence, a uniform gain factor of 4 increase in the fluctuations over the studied range of frequencies is observed, due to small-scale self-focusing.",

keywords = "high-power laser, nonlinear pulse interaction, post-compression, self-phase modulation",

author = "Bleotu, \{P. G.\} and J. Wheeler and Mironov, \{S. Yu\} and V. Ginzburg and M. Masruri and A. Naziru and R. Secareanu and D. Ursescu and F. Perez and \{De Sousa\}, J. and D. Badarau and E. Veuillot and P. Audebert and E. Khazanov and G. Mourou",

note = "Publisher Copyright: {\textcopyright} 2023 The Author(s). Published by Cambridge University Press in association with Chinese Laser Press.",

year = "2023",

month = feb,

day = "16",

doi = "10.1017/hpl.2023.10",

language = "English",

volume = "11",

journal = "High Power Laser Science and Engineering",

issn = "2052-3289",

}

TY - JOUR

T1 - Post-compression of high-energy, sub-picosecond laser pulses

AU - Bleotu, P. G.

AU - Wheeler, J.

AU - Mironov, S. Yu

AU - Ginzburg, V.

AU - Masruri, M.

AU - Naziru, A.

AU - Secareanu, R.

AU - Ursescu, D.

AU - Perez, F.

AU - De Sousa, J.

AU - Badarau, D.

AU - Veuillot, E.

AU - Audebert, P.

AU - Khazanov, E.

AU - Mourou, G.

PY - 2023/2/16

Y1 - 2023/2/16

N2 - The post-compression technique based on self-phase modulation of high-energy pulses leads to an increase in achievable peak power and intensity. Typically, the pulses considered in experiments have been less than 100 fs in duration. Here, the method is applied to the ELFIE laser system at the LULI facility, for a pulse of 7 J energy and an initial measured duration of 350 fs. A 5-mm-thick fused silica window and a 2 mm cyclic-olefin polymer were used as optical nonlinear materials. The 9 cm diameter beam was spectrally broadened to a bandwidth corresponding to 124 fs Fourier-limited pulse duration, and then it was partly post-compressed to 200 fs. After measuring the spatial spectra of the beam fluence, a uniform gain factor of 4 increase in the fluctuations over the studied range of frequencies is observed, due to small-scale self-focusing.

AB - The post-compression technique based on self-phase modulation of high-energy pulses leads to an increase in achievable peak power and intensity. Typically, the pulses considered in experiments have been less than 100 fs in duration. Here, the method is applied to the ELFIE laser system at the LULI facility, for a pulse of 7 J energy and an initial measured duration of 350 fs. A 5-mm-thick fused silica window and a 2 mm cyclic-olefin polymer were used as optical nonlinear materials. The 9 cm diameter beam was spectrally broadened to a bandwidth corresponding to 124 fs Fourier-limited pulse duration, and then it was partly post-compressed to 200 fs. After measuring the spatial spectra of the beam fluence, a uniform gain factor of 4 increase in the fluctuations over the studied range of frequencies is observed, due to small-scale self-focusing.

KW - high-power laser

KW - nonlinear pulse interaction

KW - post-compression

KW - self-phase modulation

UR - https://www.scopus.com/pages/publications/85149022240

U2 - 10.1017/hpl.2023.10

DO - 10.1017/hpl.2023.10

M3 - Article

AN - SCOPUS:85149022240

SN - 2052-3289

VL - 11

JO - High Power Laser Science and Engineering

JF - High Power Laser Science and Engineering

M1 - e30

ER -

Post-compression of high-energy, sub-picosecond laser pulses

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Keywords

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