Scalability of components for kW-level average power few-cycle lasers

Steffen Hädrich; Jan Rothhardt; Stefan Demmler; Maxim Tschernajew; Armin Hoffmann; Manuel Krebs; Andreas Liem; Oliver de Vries; Marco Plötner; Simone Fabian; Thomas Schreiber; Jens Limpert; Andreas Tünnermann

doi:10.1364/AO.55.001636

Applied Optics
Vol. 55,
Issue 7,
pp. 1636-1640
(2016)
•https://doi.org/10.1364/AO.55.001636

Scalability of components for kW-level average power few-cycle lasers

Steffen Hädrich, Jan Rothhardt, Stefan Demmler, Maxim Tschernajew, Armin Hoffmann, Manuel Krebs, Andreas Liem, Oliver de Vries, Marco Plötner, Simone Fabian, Thomas Schreiber, Jens Limpert, and Andreas Tünnermann

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Steffen Hädrich, Jan Rothhardt, Stefan Demmler, Maxim Tschernajew, Armin Hoffmann, Manuel Krebs, Andreas Liem, Oliver de Vries, Marco Plötner, Simone Fabian, Thomas Schreiber, Jens Limpert, and Andreas Tünnermann, "Scalability of components for kW-level average power few-cycle lasers," Appl. Opt. 55, 1636-1640 (2016)

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Abstract

In this paper, the average power scalability of components that can be used for intense few-cycle lasers based on nonlinear compression of modern femtosecond solid-state lasers is investigated. The key components of such a setup, namely, the gas-filled waveguides, laser windows, chirped mirrors for pulse compression and low dispersion mirrors for beam collimation, focusing, and beam steering are tested under high-average-power operation using a kilowatt cw laser. We demonstrate the long-term stable transmission of kW-level average power through a hollow capillary and a Kagome-type photonic crystal fiber. In addition, we show that sapphire substrates significantly improve the average power capability of metal-coated mirrors. Ultimately, ultrabroadband dielectric mirrors show negligible heating up to 1 kW of average power. In summary, a technology for scaling of few-cycle lasers up to 1 kW of average power and beyond is presented.

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Applied Optics