Millijoule few-cycle pulses from staged compression for strong and high field science

M. Stanfield; N. F. Beier; S. Hakimi; H. Allison; D. Farinella; A. E. Hussein; T. Tajima; F. Dollar

doi:10.1364/OE.417404

Millijoule few-cycle pulses from staged compression for strong and high field science

M. Stanfield, N. F. Beier, S. Hakimi, H. Allison, D. Farinella, A. E. Hussein, T. Tajima, F. Dollar

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

16 Scopus citations

Abstract

Intense few-cycle laser pulses have a breadth of applications in high energy density science, including particle acceleration and x-ray generation. Multi-amplifier laser system pulses have durations of tens of femtoseconds or longer. To achieve high intensities at the single-cycle limit, a robust and efficient post-compression scheme is required. We demonstrate a staged compression technique using self-phase modulation in thin dielectric media, in which few-cycle pulses can be produced. The few-cycle pulse is then used to generate extreme ultravoilet light via high harmonic generation at strong field intensities and to generate MeV electron beams via laser solid interactions at relativistic intensities.

Original language	English (US)
Pages (from-to)	9123-9136
Number of pages	14
Journal	Optics Express
Volume	29
Issue number	6
DOIs	https://doi.org/10.1364/OE.417404
State	Published - Mar 15 2021
Externally published	Yes

Bibliographical note

Funding Information:
National Science Foundation (DGE-1633631, DMR-1548924, PHY-1753165). This work was supported by STROBE: A National Science Foundation Science & Technology Center under Grant No. DMR-1548924. This material is based upon work supported by the National Science Foundation under the CAREER program Grant No. PHY-1753165, and under grant number DGE-1633631.

Publisher Copyright:
© 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

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abstract = "Intense few-cycle laser pulses have a breadth of applications in high energy density science, including particle acceleration and x-ray generation. Multi-amplifier laser system pulses have durations of tens of femtoseconds or longer. To achieve high intensities at the single-cycle limit, a robust and efficient post-compression scheme is required. We demonstrate a staged compression technique using self-phase modulation in thin dielectric media, in which few-cycle pulses can be produced. The few-cycle pulse is then used to generate extreme ultravoilet light via high harmonic generation at strong field intensities and to generate MeV electron beams via laser solid interactions at relativistic intensities.",

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AU - Stanfield, M.

AU - Beier, N. F.

AU - Hakimi, S.

AU - Allison, H.

AU - Farinella, D.

AU - Hussein, A. E.

AU - Tajima, T.

AU - Dollar, F.

N1 - Funding Information: National Science Foundation (DGE-1633631, DMR-1548924, PHY-1753165). This work was supported by STROBE: A National Science Foundation Science & Technology Center under Grant No. DMR-1548924. This material is based upon work supported by the National Science Foundation under the CAREER program Grant No. PHY-1753165, and under grant number DGE-1633631. Publisher Copyright: © 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

PY - 2021/3/15

Y1 - 2021/3/15

N2 - Intense few-cycle laser pulses have a breadth of applications in high energy density science, including particle acceleration and x-ray generation. Multi-amplifier laser system pulses have durations of tens of femtoseconds or longer. To achieve high intensities at the single-cycle limit, a robust and efficient post-compression scheme is required. We demonstrate a staged compression technique using self-phase modulation in thin dielectric media, in which few-cycle pulses can be produced. The few-cycle pulse is then used to generate extreme ultravoilet light via high harmonic generation at strong field intensities and to generate MeV electron beams via laser solid interactions at relativistic intensities.

AB - Intense few-cycle laser pulses have a breadth of applications in high energy density science, including particle acceleration and x-ray generation. Multi-amplifier laser system pulses have durations of tens of femtoseconds or longer. To achieve high intensities at the single-cycle limit, a robust and efficient post-compression scheme is required. We demonstrate a staged compression technique using self-phase modulation in thin dielectric media, in which few-cycle pulses can be produced. The few-cycle pulse is then used to generate extreme ultravoilet light via high harmonic generation at strong field intensities and to generate MeV electron beams via laser solid interactions at relativistic intensities.

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Millijoule few-cycle pulses from staged compression for strong and high field science

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