Future LASE Plans to Characterize WbLS for BUTTON Detector

E. Gunger,A. Enqvist,S. Dazeley, A. Bernstein,J. Hecla

2024 IEEE Nuclear Science Symposium (NSS), Medical Imaging Conference (MIC) and Room Temperature Semiconductor Detector Conference (RTSD)（2024）

University of Florida

Cited 0|Views4

Abstract

The Livermore Attenuation and Scattering Experiment (LASE) system was designed to quantify the attenuation and scattering of diverse candidate fill materials throughout the visible spectrum. LASE is an optical property measurement device for candidate liquids for neutrino detectors. It is designed as a horizontal and adjustable path-length attenuation and scattering system that operates in complete isolation from the atmosphere with a high degree of vibration insensitivity. Scattering measurements are available at multiple angles and adjustable beam polarization angles which allows for reliable quantitative scattering measurements and phase-function reconstruction. Attenuation measurements are made by measuring changes in laser beam intensity as a function of liquid column length. The performance of the device was benchmarked using deionized (DI) water. and found to accurately determine the optical properties of candidate fill materials for neutrino detectors. In the near future, a similar device will be installed at the Boulby Underground Technology Testbed Observing Neutrinos (BUTTON). BUTTON is a technology testbed for evaluating liquids and purification systems for neutrino and dark matter detectors.

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