Compact, folded multi-pass cells for energy scaling of post-compression

Arthur Sch\"onberg (1); Supriya Rajhans (1; 2); Esmerando Escoto; (1); Nikita Khodakovskiy (1); Victor Hariton (1); Bonaventura Farace (1),; Kristjan P\~oder (1); Ann-Kathrin Raab (3); Saga Westerberg (3); Mekan; Merdanov (3); Anne-Lise Viotti (3); Cord L. Arnold (3); Wim P. Leemans (1),; Ingmar Hartl (1); and Christoph M. Heyl (1; 4; 5)

arXiv:2409.02542·physics.optics·September 5, 2024

Compact, folded multi-pass cells for energy scaling of post-compression

Arthur Sch\"onberg (1), Supriya Rajhans (1, 2), Esmerando Escoto, (1), Nikita Khodakovskiy (1), Victor Hariton (1), Bonaventura Farace (1),, Kristjan P\~oder (1), Ann-Kathrin Raab (3), Saga Westerberg (3), Mekan, Merdanov (3), Anne-Lise Viotti (3), Cord L. Arnold (3)

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TL;DR

This paper introduces a compact, energy-scalable multi-pass cell design for ultrafast laser pulse post-compression, enabling high pulse energies in a smaller setup and demonstrating significant pulse shortening from 1 ps to 51 fs.

Contribution

The authors develop a novel folded multi-pass cell configuration that significantly reduces setup size while maintaining high energy scalability for ultrafast laser pulse post-compression.

Findings

01

Successfully compressed 8 mJ pulses from 1 ps to 51 fs in atmospheric air.

02

Demonstrated potential for scaling up to 200 mJ pulse energy with a 2.5 m setup.

03

Verified the approach through experimental and numerical methods.

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…

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Taxonomy

TopicsCellular Mechanics and Interactions · Elasticity and Material Modeling