Kazuhiro Terasawa scite author profile

An 800 ℓ liquid xenon scintillation γ ray detector is being developed for the MEG experiment which will search for µ + → e + γ decay at the Paul Scherrer Institut. Absorption of scintillation light of xenon by impurities might possibly limit the performance of such a detector. We used a 100 ℓ prototype with an active volume of 372×372×496 mm 3 to study the scintillation light absorption. We have developed a method to evaluate the light absorption, separately from elastic scattering of light, by measuring cosmic rays and α sources. By using a suitable purification technique, an absorption length longer than 100 cm has been achieved. The effects of the light absorption on the energy resolution are estimated by Monte Carlo simulation.

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Comparisons of LET Distributions for Protons with Energies between 50 and 200 MeV Determined Using a Spherical Tissue-Equivalent Proportional Counter (TEPC) and a Position-Sensitive Silicon Spectrometer (RRMD-III)

Borak

Doke

Fuse

et al. 2004

Radiation Research

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Experiments have been performed to measure the response of a spherical tissue-equivalent proportional counter (TEPC) and a silicon-based LET spectrometer (RRMD-III) to protons with energies ranging from 50-200 MeV. This represents a large portion of the energy distribution for trapped protons encountered by astronauts in low-Earth orbit. The beam energies were obtained using plastic polycarbonate degraders with a monoenergetic beam that was extracted from a proton synchrotron. The LET spectrometer provided excellent agreement with the expected LET distribution emerging from the energy degraders. The TEPC cannot measure the LET distribution directly. However, the frequency mean value of lineal energy, y(-)(f), provided a good approximation to LET. This is in contrast to previous results for high-energy heavy ions where y(-)(f) underestimated LET, whereas the dose-averaged lineal energy, y(-)(D), provided a good approximation to LET.

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Liquid xenon scintillation calorimetry and Xe optical properties

Baldini

Bemporad

Cei

et al. 2006

IEEE Trans. Dielect. Electr. Insul.

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The optical properties of LXe in the vacuum ultra violet (VUV), determining the performance of a scintillation calorimeter, are discussed in detail. The available data, measured in a wider spectral region from visible to UV light, and in a large range of Xe densities, from gas to liquid, are examined. It is shown that this information can be used for deriving the LXe optical properties in the VUV. A comparison is made with the few direct measurements in LXe for VUV light resulting from the LXe excitation by ionizing particles. A useful relation is obtained which connects the Rayleigh scattering length to the refractive index in LXe.

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Development of a liquid-xenon photon detector––towards the search for a muon rare decay mode at Paul Scherrer Institute

Mihara¹,

Doke²,

Haruyama³

et al. 2004

Cryogenics

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Measurements of LET-distribution, dose equivalent and quality factor with the RRMD-III on the Space Shuttle Missions STS-84, -89 and -91

Doke

Hayashi

Kikuchi

et al. 2001

Radiation Measurements

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