Generation of a high-energy picosecond laser pulse with a high-contrast ratio by chirped-pulse amplification
- 1 February 1991
- journal article
- Published by Institute of Electrical and Electronics Engineers (IEEE) in IEEE Journal of Quantum Electronics
- Vol. 27 (2) , 288-294
- https://doi.org/10.1109/3.78233
Abstract
The generation of a 1.052- mu m laser pulse of 3.5-ps duration and 28-J energy by fiber-grating chirped-pulse amplification in a large-aperture Nd-glass laser system is reported. A novel technique that significantly improves the contrast ratio was used, resulting in a pulse with 8-TW peak power and a contrast ratio of better than 900, limited by the dynamic range of the detection system. The high contrast ratio was obtained by selecting only only the central portion of the frequency-chirped pulse where the chirp is positive and linear. The high-intensity compressed pulse thus generated was frequency-upconverted to 526 nm with a 40% conversion efficiency.<>Keywords
This publication has 32 references indexed in Scilit:
- Single-shot measurement of duration and contrast of high-power picosecond pulsesPublished by SPIE-Intl Soc Optical Eng ,1990
- High-Density Plasmas Produced by Ultrafast Laser PulsesPhysical Review Letters, 1989
- Generation and application of ultrafast X-ray sourcesIEEE Journal of Quantum Electronics, 1989
- Cascade Focusing in the Beat-Wave AcceleratorPhysical Review Letters, 1988
- Effect of laser pulse duration on short wavelength emission from femtosecond and picosecond laser-produced Ta plasmasApplied Physics Letters, 1988
- Generation of ultrashort x-ray pulsesPhysical Review A, 1988
- Observation of Asymmetric Stark Profiles from Plasmas Created by a Picosecond KrF LaserPhysical Review Letters, 1987
- X-ray characterization of picosecond laser plasmasOptics Communications, 1987
- Spectral windowing of frequency-modulated optical pulses in a grating compressorApplied Physics Letters, 1985
- High efficiency frequency tripling schemes for high-power Nd: Glass lasersIEEE Journal of Quantum Electronics, 1981