1. Single-longitudinal-mode pumped pulsed-dye amplifier for high-resolution laser spectroscopy
- Author
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C. Granados, Rafael Ferrer, M. Verlinde, S. Kraemer, A. Claessens, P. Van Duppen, D. Li, E. Verstraelen, P. Van den Bergh, and Yu. Kudryavtsev
- Subjects
Materials science ,Sideband ,business.industry ,Amplifier ,Physics::Optics ,02 engineering and technology ,Laser ,7. Clean energy ,01 natural sciences ,law.invention ,010309 optics ,Longitudinal mode ,020210 optoelectronics & photonics ,Optics ,law ,0103 physical sciences ,0202 electrical engineering, electronic engineering, information engineering ,Continuous wave ,Physics::Atomic Physics ,Laser power scaling ,business ,Spectroscopy ,Instrumentation ,Hyperfine structure - Abstract
The In-Gas-jet Laser Ionization and Spectroscopy (IGLIS) technique relies on narrow-bandwidth, high-peak-power, short-pulse-length (≈10 ns), and high-repetition-rate laser pulses to probe, precisely and efficiently, the hyperfine structure of medium-heavy and heavy isotopes, embedded in a supersonic jet. The power and repetition rate requirements of the laser system are met by combining ≈100 W, 8 ns pulse width, 10 kHz commercial Nd:YAG pump lasers with a single-mode continuous wave seeded Pulsed Dye Amplifier (PDA). The common multi-longitudinal-mode operation of these Nd:YAG pump lasers causes, however, undesirable frequency sidebands in the output spectrum of the PDA system, hindering the attainable spectral resolution, a correct interpretation, and an accurate analysis of the hyperfine spectra. In this article, a new prototype Nd:YAG laser is presented, which combined with the PDA system is capable of providing quasi-transform-limited laser pulses at 10 kHz, with only limited losses in laser power. This system reduces any spectral sideband amplitude below a proven upper limit of 0.2% with one order of magnitude extra reduction expected based on simulations. A full characterization of both the Nd:YAG and PDA laser systems is done by studying the temporal and frequency behavior in detail. This study is finalized by a performance benchmark of this combined laser system in the hyperfine spectroscopy of copper isotopes, showcasing its applicability for future IGLIS studies.
- Published
- 2020
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