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nhelix is the Nanosecond High Energy Laser for Ion beam eXperiments |
| Operating wavelength |
1064 nm |
| Pulse length |
4 - 15 ns or 500 ps |
| Max. output energy |
100 J or 10 J |
| Max. output power |
10 GW |
| Frontend |
CONTINUUM Powerlite Precision 8000
Geola G-Mini-GSI
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| Oscillator concept |
Q-switch (Pockels cell)
injection seeded |
| No. of amplifiers |
6 (Nd:glass ) |
| Size of amplifiers [mm] |
16, 25, 32, 45, 45, 64 |
| No. of Spatial Filters |
10 |
| No. of Faraday rotators |
2 |
Technical data of the nhelix laser system
Side view of the nanosecond front end (Powerlight 800, Continuum) and the injection into the amplification
beam line. The oscillator is generating pulses with an energy of approximately 150 mJ and a pulse duration of
15 ns (FWHM). A Pockels cell downstreams allows to shaping the pulse to pulse lengths between 4 and
15 ns with a defined rising/falling edge of 3 ns. The pulse frequency for a thermaly stable operation
of the oscillator is 10 Hz.
Injection of the two laser beams (Powerlight 4-15 ns, Geola 0.5 ns) into the amplification beam
including beam shaping elements and the pockels cell.
View of the optical table containing the double/triple pass amplifiers, spatial filters and laser beam diagnostics.
Top view into the target chamber. The target is placed in the middle of the chamber
(bright spot). It can be irradiated by the PHELIX laser (from the top) and/or the
nhelix laser (over the mirors from top or down) to heat it to a plasma as well as by
a diagnostic beam for laser interferomerty. At the same time, a heavy ion beam (from bottom)
can penetrate the target plasma to probe the interaction mechanisms.
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