Yunchang Shin scite author profile

Liquid-argon scintillation detectors are used in fundamental physics experiments and are being considered for security applications. Previous studies have suggested that the addition of small amounts of xenon dopant improves performance in light or signal yield, energy resolution, and particle discrimination. In this study, we investigate the detector response for xenon dopant concentrations from 9 ± 5 ppm to 1100 ± 500 ppm xenon (by weight) in 6 steps. The 3.14-liter detector uses tetraphenyl butadiene (TPB) wavelength shifter with dual photomultiplier tubes and is operated in single-phase mode. Gamma-ray-interaction signal yield of 4.0 ± 0.1 photoelectrons/keV improved to 5.0 ± 0.1 photoelectrons/keV with dopant. Energy resolution at 662 keV improved from (4.4 ± 0.2)% (σ) to (3.5 ± 0.2)% (σ) with dopant. Pulseshape discrimination performance degraded greatly at the first addition of dopant, slightly improved with additional additions, then rapidly improved near the end of our dopant range, with performance becoming slightly better than pure argon at the highest tested dopant concentration. Some evidence of reduced neutron scintillation efficiency with increasing dopant concentration was observed. Finally, the waveform shape outside the TPB region is discussed, suggesting that the contribution to the waveform from xenon-produced light is primarily in the last portion of the slow component.

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Erratum: Cold Neutron Energy Dependent Production of Ultracold Neutrons in Solid Deuterium [Phys. Rev. Lett.99, 262502 (2007)]

Atchison¹,

Blau²,

Bodek³

et al. 2008

Phys. Rev. Lett.

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Investigation of solid , and for ultracold neutron production

Atchison

Blau

Bodek

et al. 2009

Nuclear Instruments and Methods in Physics Research Section A:

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Progress on the ARIADNE Axion Experiment

Fosbinder-Elkins

Lohmeyer

Dargert

et al. 2018

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Scintillation and charge yield from the tracks of energetic electrons in superfluid helium-4

Guo¹,

Dufault²,

Cahn³

et al. 2012

J. Inst.

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An energetic electron passing through liquid helium causes ionization along its track. The ionized electrons quickly recombine with the resulting positive ions, which leads to the production of prompt scintillation light. By applying appropriate electric fields, some of the ionized electrons can be separated from their parent ions. The fraction of the ionized electrons extracted in a given applied field depends on the separation distance between the electrons and the ions. We report the determination of the mean electron-ion separation distance for charge pairs produced along the tracks of beta particles in superfluid helium at 1.5 K by studying the quenching of the scintillation light under applied electric fields. Knowledge of this mean separation parameter will aid in the design of particle detectors that use superfluid helium as a target material.

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Yunchang Shin

Pulse-shape discrimination and energy resolution of a liquid-argon scintillator with xenon doping

Erratum: Cold Neutron Energy Dependent Production of Ultracold Neutrons in Solid Deuterium [Phys. Rev. Lett.99, 262502 (2007)]

Investigation of solid , and for ultracold neutron production

Progress on the ARIADNE Axion Experiment

Scintillation and charge yield from the tracks of energetic electrons in superfluid helium-4

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