Kilowatt-average-power compression of millijoule pulses in a gas-filled multi-pass cell

Grebing, Christian; Müller, Michael; Buldt, Joachim; Stark, Henning; Limpert, Jens

doi:10.1364/ol.408998

Cited by 94 publications

(46 citation statements)

References 27 publications

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“…Evaluating the overlap of the offaxis spectra with the on-axis spectrum as defined in Ref. [29] yields an effective homogeneity of 97.5%, proving that no significant degradation occurred with respect to the input [18]. This measurement is a lower-bound estimate as the result is limited by the low signal-to-noise-ratio for wavelengths larger than 1.1 µm.…”

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confidence: 81%

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confidence: 99%

“…An alternative could be nonlinear compression in multipass cells [14][15][16], which recently has been demonstrated at 112 mJ pulse energy [17] and at 1 kW average output power [18]. These cells feature an excellent transmission of up to 96% [18] and a high resilience to beam quality imperfections and pointing instabilities due to their extended free aperture, which allows for straightforward power scaling. Hence, these cells were ideal candidates for high-power nonlinear pulse compression to the few-cycle regime, if not the reflection bandwidth of the typical dielectric mirrors used would limit the pulse duration to about 30 fs.…”

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confidence: 99%

“…The laser emits pulses at 500 kHz repetition rate with approximately 1 mJ pulse energy and 200 fs pulse duration. Nonlinear spectral broadening in a first, argon-filled, dielectricmirror Herriott cell and chirped-mirror compression reduces the pulse duration to 31 fs [18]. After this stage, the collimated beam features a 1/e 2 -diameter of 8 mm and an average power of 474 W. The beam continues into a second multipass cell comprising 13 individual 1"-diameter, dielectrically enhanced silver-coated silicon mirrors (RM>98.5%, |GDD|<10fs 2 , 800-1300 nm).…”

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Multipass cell for high-power few-cycle compression

et al. 2021

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A multipass cell for nonlinear compression to few-cycle pulse duration is introduced comprising dielectrically enhanced silver mirrors on silicon substrates. Spectral broadening with 388 W output average power and 776 µJ pulse energy is obtained at 82% cell transmission. A high output beam quality (M 2 <1.2) and a high spatio-spectral homogeneity (97.5%) as well as the compressibility of the output pulses to 6.9 fs duration are demonstrated. Finite element analysis reveals scalability of this cell to 2 kW average output power.

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confidence: 81%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Multipass cell for high-power few-cycle compression

et al. 2021

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“…Recently, a new method based on nonlinear spectral broadening within multi-pass cells (MPC) was introduced [11,12]. The method offers high transmission [13,14], high-power handling [14,15], excellent beam quality [13,16] and large compression ratios [16,17] while being easily adaptable to a large variety of laser pulse parameters including durations ranging currently from 10 ps [18] to few-cycles [17,19,20] as well as pulse energies ranging from a few µJ [21] to more than 100 mJ [22].…”

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confidence: 99%

High-energy bow tie multi-pass cells for nonlinear spectral broadening applications

et al. 2022

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Multi-pass cells have emerged as very attractive tools for spectral broadening and post-compression applications. We discuss pulse energy limitations of standard multi-pass cells considering basic geometrical scaling principles and introduce a novel energy scaling method using a multi-pass cell arranged in a bow tie geometry. Employing nonlinear pulse propagation simulations, we numerically demonstrate the compression of 125mJ, 1 ps pulses to 50 fs using a compact 2 m long setup and outline routes to extend our approach into the Joule-regime.

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Nonlinear Optics in Multipass Cells

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et al. 2021

Laser & Photonics Reviews

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The fundamental principles and experimental implementations of multipass cells used as a platform for nonlinear optics are reviewed. Embedding a nonlinear medium in a multipass cell allows for a distribution of the nonlinearity over large interaction distances, while the beam goes through multiple foci, conferring on the beam a robustness with respect to spatio-spectral coupling effects. Most of the research so far has been focused on temporal compression based on self-phase modulation, with excellent performances especially in terms of energy scaling and throughput. However, other nonlinear phenomena and functions are being increasingly investigated, such as supercontinuum generation, spectral compression, or Raman scattering. Nonlinear optics experiments in multipass cells bear some similarities with the work done in optical fibers over several decades, while allowing straightforward energy scaling potential, and unlocking engineering possibilities through the design of the cell mirrors, geometry, and nonlinear medium.

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Kilowatt-average-power compression of millijoule pulses in a gas-filled multi-pass cell

Cited by 94 publications

References 27 publications

Multipass cell for high-power few-cycle compression

Multipass cell for high-power few-cycle compression

High-energy bow tie multi-pass cells for nonlinear spectral broadening applications

Nonlinear Optics in Multipass Cells

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