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Kvantovaya Elektronika, 2007, Volume 37, Number 8, Pages 697–705 (Mi qe13564)  

This article is cited in 13 scientific papers (total in 13 papers)

Selected papers reported at the conference 'Laser Optics 2006'

Development of a yearlong maintenance-free terawatt Ti:Sapphire laser system with a 3D UV-pulse shaping system for THG

H. Tomizawaa, H. Dewaa, H. Hanakia, F. Matsuib

a Accelerator Division, Japan Synchrotron Radiation Research Institute, Japan
b Creative & Advanced Department, Industrial Technology Center of Fukui Prefecture, Japan
Abstract: Laser sources that feature a controlled pulse shape and long-term stability are required in a wide range of scientific fields. We developed a maintenance-free 3D-shaped UV-laser system for the photoinjector (RF gun photocathode) of an X-ray SASE free electron laser (FEL). The laser pulse-energy stability was improved to 0.2% – 0.3% (rms, 10 pps, 0.4 TW in femtosecond operation) at the fundamental wavelength and to 0.7% – 1.4% at the third-harmonic wavelength. This stability was continuously maintained for five months, 24 hours a day. Such improvement reflects an ability to stabilise the laser system in a humidity-controlled clean room. The pulse-energy stability of a mode-locked femtosecond oscillator was continuously held at 0.3% (p–p) for five months, 24 hours a day. In addition, the ideal spatial and temporal profiles of a shot-by-shot single UV-laser pulse are essential to suppress the emittance of the electron-beam pulse generated by the photocathode of the RF gun. We apply a deformable mirror that automatically shapes the spatial UV-laser profile with a feedback routine, based on a genetic algorithm, and a pulse stacker for temporal shaping at the same time. The 3D shape of the laser pulse is spatially top-hat (flattop) and temporally – a square stacked pulse. We apply the Q-scan method to evaluate the emittance of the electron beam generated by a 3D-shaped laser pulse. By using a 3D-shaped laser pulse of diameter 0.8 mm on the cathode and duration 10 ps (FWHM), we obtain a minimum horizontal normalised emittance of 1.4π mm mrad with beam energy of 26 MeV, holding its net charge to a 0.4 nC pulse-1. At a higher net charge of 1.0 nC pulse-1, the minimum beam emittance is 2.3π mm mrad with equivalent diameter and a longer pulse duration of 20 ps (FWHM). In this study, we demonstrate 3D shaping [both temporal (1D) and spatial (2D)] short pulse (5 – 20ps) laser beam as an ideal light source for yearlong stable generation of a low emittance electron beam with a high charge (1 – 2 nC pulse-1). Here, we report the principle and development process of our beam-quality control systems.
Received: 12.03.2007
English version:
Quantum Electronics, 2007, Volume 37, Issue 8, Pages 697–705
DOI: https://doi.org/10.1070/QE2007v037n08ABEH013564
Bibliographic databases:
Document Type: Article
PACS: 42.55.Rz, 42.65.Re, 41.60.Cr
Language: Russian
Supplementary materials:
pict13564.pdf (890.0 Kb)


Citation: H. Tomizawa, H. Dewa, H. Hanaki, F. Matsui, “Development of a yearlong maintenance-free terawatt Ti:Sapphire laser system with a 3D UV-pulse shaping system for THG”, Kvantovaya Elektronika, 37:8 (2007), 697–705 [Quantum Electron., 37:8 (2007), 697–705]
Linking options:
  • https://www.mathnet.ru/eng/qe13564
  • https://www.mathnet.ru/eng/qe/v37/i8/p697
  • This publication is cited in the following 13 articles:
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
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