The SAS Gamma-Ray Spectrometer For High Repetition Rate Laser Applications
ORAL
Abstract
A new type of compact high-resolution high-sensitivity gamma-ray spectrometer for short-pulse
0.5-50 MeV gamma-rays has been developed by combining the principles of pixelated scintillators
and attenuation spectrometers. The first prototype of this scintillator attenuation
spectrometer (SAS) was tested successfully on Trident laser experiments and later improved
versions have been used extensively in Texas Petawatt laser experiments in Austin TX and
OMEGA-EP laser experiments at LLE, Rochester NY. The SAS spectrometer is ideally suited
to diagnose gamma-rays from high-repetition-rate laser and HED experiments since it does not require the
use of image plates or radiographic films. Instead the scintillation light profiles are recorded
by a CCD camera with millisecond time exposure. Hence the SAS can be used in laser and HED
experiments of up to kHz repetition rates. Here we provide a concise description of the design principles,
capabilities and preliminary results of the SAS from recent short-pulse laser experiments.
0.5-50 MeV gamma-rays has been developed by combining the principles of pixelated scintillators
and attenuation spectrometers. The first prototype of this scintillator attenuation
spectrometer (SAS) was tested successfully on Trident laser experiments and later improved
versions have been used extensively in Texas Petawatt laser experiments in Austin TX and
OMEGA-EP laser experiments at LLE, Rochester NY. The SAS spectrometer is ideally suited
to diagnose gamma-rays from high-repetition-rate laser and HED experiments since it does not require the
use of image plates or radiographic films. Instead the scintillation light profiles are recorded
by a CCD camera with millisecond time exposure. Hence the SAS can be used in laser and HED
experiments of up to kHz repetition rates. Here we provide a concise description of the design principles,
capabilities and preliminary results of the SAS from recent short-pulse laser experiments.
*This work was partially supported by DOE grants DE-SC0021327 and DE-SC0016505.
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Publication: Paper to be submitted to Rev. of Sci. Instr. Preprint available at http://arxiv.org/abs/1904.08536
Presenters
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Edison P Liang
- Rice University
- Rice Univ