Journal Article

PUBDB-2024-05748

http://join2-wiki.gsi.de/foswiki/pub/Main/Artwork/join2_logo100x88.png Compact, folded multi-pass cells for energy scaling of post-compression

Schoenberg, A. (Corresponding author)DESY* ; Rajhans, S.DESY* ; Escoto, E.DESY* ; Khodakovskiy, N.DESY* ; Hariton, V.DESY* ; Farace, B.DESY* ; Poder, K.DESY* ; Raab, A.-K.Extern* ; Westerberg, S.Extern* ; Merdanov, M.Extern* ; Viotti, A.-L.Extern* ; Arnold, C.Extern* ; Leemans, W.DESY* ; Hartl, I.DESY* ; Heyl, C.DESY*

2025
OPTICA Washington, DC

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Please use a persistent id in citations: doi:10.1364/PRJ.540977  doi:10.3204/PUBDB-2024-05748

Abstract: Combining high peak- and high average power has long been a key challenge of ultrafast laser technology, crucial for applications such as laser-plasma acceleration and strong-field physics. A promising solution lies in post-compressed ytterbium lasers, but scaling these to high pulse energies presents a major bottleneck. Post-compression techniques, particularly Herriott-type multi-pass cells (MPCs), have enabled large peak power boosts at high average powers but their pulse energy acceptance reaches practical limits defined by setup size and coating damage threshold. In this work, we address this challenge and demonstrate a novel type of compact, energy-scalable MPC (CMPC). By employing a novel MPC configuration and folding the beam path, the CMPC introduces a new degree of freedom for downsizing the setup length, enabling compact setups even for large pulse energies. We experimentally and numerically verify the CMPC approach, demonstrating post-compression of 8 mJ pulses from 1 ps down to 51 fsin atmospheric air using a cell roughly 45 cm in length at low fluence values. Additionally, we discuss the potential for energy scaling up to 200 mJ with a setup size reaching 2.5 m. Our work presents a new approach to high-energy post-compression, with up-scaling potential far beyond the demonstrated parameters. This opens new routes for achieving the high peak and average powers necessary for demanding applications of ultrafast lasers.

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Contributing Institute(s):

1. Photonics Research and Development (FS-PRI)
2. Laser Forschung und Entwicklung (FS-LA)
3. Lund University (LUND)
4. Plasma Accelerators (MPA)
5. externe Institute im Bereich Photon Science (HI Jena)
6. Helmholtz-Zentrum für Schwerionenforschung (GSI)

Research Program(s):

1. 621 - Accelerator Research and Development (POF4-621) (POF4-621)
2. HIRS-0018 - Helmholtz-Lund International School - Intelligent instrumentation for exploring matter at different time and length scales (HELIOS) (2020_HIRS-0018) (2020_HIRS-0018)

Experiment(s):

1. No specific instrument

Appears in the scientific report 2025

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