Wavelength-shifting performance of polyethylene naphthalate films in a liquid argon environment

Y. Abraham; J. Asaadi; V. Basque; W. Castiglioni; R. Dorrill; M. Febbraro; B. Hackett; J. Kelsey; B. R. Littlejohn; I. Parmaksiz; M. Rooks; A. M. Szelc

doi:10.1088/1748-0221/16/07/P07017

Wavelength-shifting performance of polyethylene naphthalate films in a liquid argon environment

Y. Abraham, J. Asaadi, V. Basque, W. Castiglioni, R. Dorrill, M. Febbraro, B. Hackett, J. Kelsey, B. R. Littlejohn, I. Parmaksiz, M. Rooks, A. M. Szelc

Nuclear Structure and Nuclear Astrophysi

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10 Scopus citations

Abstract

Liquid argon is commonly used as a detector medium for neutrino physics and dark matter experiments in part due to its copious scintillation light production in response to its excitation and ionization by charged particle interactions. As argon scintillation appears in the vacuum ultraviolet (VUV) regime and is difficult to detect, wavelength-shifting materials are typically used to convert VUV light to visible wavelengths more easily detectable by conventional means. In this work, we examine the wavelength-shifting and optical properties of poly(ethylene naphthalate) (PEN), a recently proposed alternative to tetraphenyl butadiene (TPB), the most widely-used wavelength-shifter in argon-based experiments. In a custom cryostat system with well-demonstrated geometric and response stability, we use 128 nm argon scintillation light to examine various PEN-including reflective samples’ light-producing capabilities, and study the stability of PEN when immersed in liquid argon. The best-performing PEN-including test reflector was found to produce 34% as much visible light as a TPB-including reference sample, with widely varying levels of light production between different PEN-including test reflectors. Plausible origins for these variations, including differences in optical properties and molecular orientation, are then identified using additional measurements. Unlike TPB-coated samples, PEN-coated samples did not produce long-timescale light collection increases associated with solvation or suspension of wavelength-shifting material in bulk liquid argon.

Original language	English
Article number	P07017
Journal	Journal of Instrumentation
Volume	16
Issue number	7
DOIs	https://doi.org/10.1088/1748-0221/16/07/P07017
State	Published - Jul 2021

Funding

We thank Marcin Ku\u017Aniak for discussions and communications about the topic. We also thank Jos\u00E9 Alfonso Soto Ot\u00F3n for supplying a sample, and for his comments and suggestions. This work was supported by grants from the U.S. Department of Energy, Office of Science, Office of High Energy Physics under Award Numbers DE-SC0008347 and DE-SC0011686, as well as from the Science and Technology Facilities Council (STFC), part of the United Kingdom Research and Innovation; and from the Royal Society U.K. awards: RGF\\EA\\180209 and UF140089. We also acknowledge support from UT-Arlington and Illinois Institute of Technology\u2019s College of Letters and Science.

Keywords

Double-phase)
Gas
Ionization
Liquid scintillators)
Neutrino detectors
Noble liquid detectors (scintillation
Scintillation and light emission processes (solid
Scintillators

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title = "Wavelength-shifting performance of polyethylene naphthalate films in a liquid argon environment",

abstract = "Liquid argon is commonly used as a detector medium for neutrino physics and dark matter experiments in part due to its copious scintillation light production in response to its excitation and ionization by charged particle interactions. As argon scintillation appears in the vacuum ultraviolet (VUV) regime and is difficult to detect, wavelength-shifting materials are typically used to convert VUV light to visible wavelengths more easily detectable by conventional means. In this work, we examine the wavelength-shifting and optical properties of poly(ethylene naphthalate) (PEN), a recently proposed alternative to tetraphenyl butadiene (TPB), the most widely-used wavelength-shifter in argon-based experiments. In a custom cryostat system with well-demonstrated geometric and response stability, we use 128 nm argon scintillation light to examine various PEN-including reflective samples{\textquoteright} light-producing capabilities, and study the stability of PEN when immersed in liquid argon. The best-performing PEN-including test reflector was found to produce 34% as much visible light as a TPB-including reference sample, with widely varying levels of light production between different PEN-including test reflectors. Plausible origins for these variations, including differences in optical properties and molecular orientation, are then identified using additional measurements. Unlike TPB-coated samples, PEN-coated samples did not produce long-timescale light collection increases associated with solvation or suspension of wavelength-shifting material in bulk liquid argon.",

keywords = "Double-phase), Gas, Ionization, Liquid scintillators), Neutrino detectors, Noble liquid detectors (scintillation, Scintillation and light emission processes (solid, Scintillators",

author = "Y. Abraham and J. Asaadi and V. Basque and W. Castiglioni and R. Dorrill and M. Febbraro and B. Hackett and J. Kelsey and Littlejohn, {B. R.} and I. Parmaksiz and M. Rooks and Szelc, {A. M.}",

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AU - Asaadi, J.

AU - Basque, V.

AU - Castiglioni, W.

AU - Dorrill, R.

AU - Febbraro, M.

AU - Hackett, B.

AU - Kelsey, J.

AU - Littlejohn, B. R.

AU - Parmaksiz, I.

AU - Rooks, M.

AU - Szelc, A. M.

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N2 - Liquid argon is commonly used as a detector medium for neutrino physics and dark matter experiments in part due to its copious scintillation light production in response to its excitation and ionization by charged particle interactions. As argon scintillation appears in the vacuum ultraviolet (VUV) regime and is difficult to detect, wavelength-shifting materials are typically used to convert VUV light to visible wavelengths more easily detectable by conventional means. In this work, we examine the wavelength-shifting and optical properties of poly(ethylene naphthalate) (PEN), a recently proposed alternative to tetraphenyl butadiene (TPB), the most widely-used wavelength-shifter in argon-based experiments. In a custom cryostat system with well-demonstrated geometric and response stability, we use 128 nm argon scintillation light to examine various PEN-including reflective samples’ light-producing capabilities, and study the stability of PEN when immersed in liquid argon. The best-performing PEN-including test reflector was found to produce 34% as much visible light as a TPB-including reference sample, with widely varying levels of light production between different PEN-including test reflectors. Plausible origins for these variations, including differences in optical properties and molecular orientation, are then identified using additional measurements. Unlike TPB-coated samples, PEN-coated samples did not produce long-timescale light collection increases associated with solvation or suspension of wavelength-shifting material in bulk liquid argon.

AB - Liquid argon is commonly used as a detector medium for neutrino physics and dark matter experiments in part due to its copious scintillation light production in response to its excitation and ionization by charged particle interactions. As argon scintillation appears in the vacuum ultraviolet (VUV) regime and is difficult to detect, wavelength-shifting materials are typically used to convert VUV light to visible wavelengths more easily detectable by conventional means. In this work, we examine the wavelength-shifting and optical properties of poly(ethylene naphthalate) (PEN), a recently proposed alternative to tetraphenyl butadiene (TPB), the most widely-used wavelength-shifter in argon-based experiments. In a custom cryostat system with well-demonstrated geometric and response stability, we use 128 nm argon scintillation light to examine various PEN-including reflective samples’ light-producing capabilities, and study the stability of PEN when immersed in liquid argon. The best-performing PEN-including test reflector was found to produce 34% as much visible light as a TPB-including reference sample, with widely varying levels of light production between different PEN-including test reflectors. Plausible origins for these variations, including differences in optical properties and molecular orientation, are then identified using additional measurements. Unlike TPB-coated samples, PEN-coated samples did not produce long-timescale light collection increases associated with solvation or suspension of wavelength-shifting material in bulk liquid argon.

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Wavelength-shifting performance of polyethylene naphthalate films in a liquid argon environment

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