Kristian Dehne scite author profile

We demonstrate the generation of 1.1 J pulses of picosecond duration at 1 kHz repetition rate (1.1 kW average power) from a diode-pumped chirped pulse amplification Yb:YAG laser. The laser employs cryogenically cooled amplifiers to generate λ = 1030 n m pulses with average power of up to 1.26 kW prior to compression with excellent beam quality. Pulses are compressed to 4.5 ps duration with 90% efficiency. This compact picosecond laser will enable a variety of applications that require high energy ultrashort pulses at kilohertz repetition rates.

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Scaling diode-pumped, high energy picosecond lasers to kilowatt average powers

Reagan

Baumgarten

Jankowska

et al. 2018

High Pow Laser Sci Eng

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Recent results in the development of diode-driven high energy, high repetition rate, picosecond lasers, including the demonstration of a cryogenic Yb:YAG active mirror amplifier that produces 1.5 J pulses at 500 Hz repetition rate (0.75 kW average power) are reviewed. These pulses are compressed resulting in the generation of ${\sim}5~\text{ps}$ duration, 1 J pulses with 0.5 kW average power. A full characterization of this high power cryogenic amplifier, including at-wavelength interferometry of the active region under ${>}1~\text{kW}$ average power pump conditions, is presented. An initial demonstration of operation at 1 kW average power (1 J, 1 kHz) is reported.

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In Situ 3-D Temperature Mapping of High Average Power Cryogenic Laser Amplifiers

Chi

Dehne

Baumgarten

et al. 2018

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In situ 3-D temperature mapping of high average power cryogenic laser amplifiers

et al. 2018

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Heat generation is a key obstacle to scaling high energy solid-state lasers to the multi-kilowatt average powers required for several key applications. We demonstrate an accurate, in situ, noninvasive optical technique to that makes three-dimensional (3-D) temperature maps within cryogenic amplifiers operating at high average power. The temperature is determined by analyzing the fluorescence spectra with a neural network function. The accuracy of the technique relies on a calibration that does not depend on simulations. Results are presented for a cryogenic Yb:YAG active mirror laser amplifier operating at different pump conditions. The technique is applicable to other solid-state lasers materials.

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Kristian Dehne

1.1 J Yb:YAG picosecond laser at 1 kHz repetition rate

Scaling diode-pumped, high energy picosecond lasers to kilowatt average powers

In Situ 3-D Temperature Mapping of High Average Power Cryogenic Laser Amplifiers

In situ 3-D temperature mapping of high average power cryogenic laser amplifiers

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