Cryogenic nanosecond and picosecond high average and peak power (HAPP) pump lasers for ultrafast applications

Cryogenic nanosecond and picosecond high average and peak power (HAPP) pump lasers for ultrafast applications

Using cryogenic laser technology, it is now possible to design and demonstrate lasers that have concomitant high average and peak powers, with near-diffraction-limited beam quality. We refer to these new laser systems as HAPP lasers. In this paper, we review important laser crystal materials propert...

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Veröffentlicht in:High power laser science and engineering 2016, Vol.4 (2), p.37-67, Article e15
Hauptverfasser: Brown, David C., Tornegård, Sten, Kolis, Joseph
Format: Artikel
Sprache:eng
Schlagworte:
Cooling
cryogenic
Cryogenic temperature
Cryopumping
Design
Heat conductivity
HEC-DPSSL Technology
Laser damage
Lasers
lasers
high-average-power
lasers
high-peak-power
lasers
ultrafast
lasers
Yb
Material properties
Optics
Power
Temperature
Temperature effects
Yield point
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Beschreibung
Zusammenfassung:Using cryogenic laser technology, it is now possible to design and demonstrate lasers that have concomitant high average and peak powers, with near-diffraction-limited beam quality. We refer to these new laser systems as HAPP lasers. In this paper, we review important laser crystal materials properties at cryogenic temperature, with an emphasis on Yb lasers, and discuss the important design considerations, including the laser-induced damage threshold, nonlinear effects and thermal effects. A comprehensive model is presented to describe diode pulsed pumping with arbitrary duration and repetition rate, and is used with the Frantz–Nodvik equation to describe, to first order, the performance of HAPP laser systems. A computer code with representative results is also described.
ISSN:2095-4719
2052-3289
DOI:10.1017/hpl.2016.12