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Scalability, scintillation readout and charge drift in a kilogram scale solid xenon particle detector

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 Added by Jonghee Yoo
 Publication date 2014
  fields Physics
and research's language is English




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We report a demonstration of the scalability of optically transparent xenon in the solid phase for use as a particle detector above a kilogram scale. We employ a liquid nitrogen cooled cryostat combined with a xenon purification and chiller system to measure the scintillation light output and electron drift speed from both the solid and liquid phases of xenon. Scintillation light output from sealed radioactive sources is measured by a set of high quantum efficiency photomultiplier tubes suitable for cryogenic applications. We observed a reduced amount of photons in solid phase compared to that in liquid phase. We used a conventional time projection chamber system to measure the electron drift time in a kilogram of solid xenon and observed faster electron drift speed in the solid phase xenon compared to that in the liquid phase.



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222 - J. Yoo , W. F. Jaskierny 2015
A study of charge drift in a large scale optically transparent solid xenon is reported. A pulsed high power xenon light source is used to liberate electrons from a photocathode. The drift speeds of the electrons are measured using a 8.7,cm long electrode in both the liquid and solid phase of xenon. In the liquid phase (163,K), the drift speed is 0.193 $pm$ 0.003 cm/$mu$s while the drift speed in the solid phase (157,K) is 0.397 $pm$ 0.006 cm/$mu$s at 900 V/cm over 8.0,cm of uniform electric fields. Therefore, it is demonstrated that a factor two faster electron drift speed in solid phase xenon compared to that in liquid in a large scale solid xenon.
128 - J. Yoo , H. Cease , W.F. Jaskierny 2015
We report a demonstration of the scalability of optically transparent xenon in the solid phase for use as a particle detector above a kilogram scale. We employed a cryostat cooled by liquid nitrogen combined with a xenon purification and chiller system. A modified {it Bridgemans technique} reproduces a large scale optically transparent solid xenon.
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