Distributed imaging for liquid scintillation detectors

Dalmasson, J.; Gratta, G.; Jamil, A.; Kravitz, S.; Malek, M.; Wells, Kevin; Bentley, Julie; Steven, Samuel; Su, Juanjuan

doi:10.1103/physrevd.97.052006

Cited by 13 publications

(12 citation statements)

References 20 publications

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“…Traditional light collectors such as Winston Cones and scintillating light guides have been rigorously pursued for the Long Baseline Neutrino Experiment (LBNE) [54] and Hyper-K [55]. Using arrays of lenses, plenoptic imaging would add directional information to detected light [56]. Novel designs using specular reflection off mirrors could also be used to enhance coverage.…”

Section: Photodetectionmentioning

confidence: 99%

Theia: an advanced optical neutrino detector

et al. 2020

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New developments in liquid scintillators, highefficiency, fast photon detectors, and chromatic photon sorting have opened up the possibility for building a large-scale detector that can discriminate between Cherenkov and scintillation signals. Such a detector could reconstruct particle direction and species using Cherenkov light while also having the excellent energy resolution and low threshold of a scintillator detector. Situated deep underground, and utilizing new techniques in computing and reconstruction, this detector could achieve unprecedented levels of background rejection, enabling a rich physics program spanning topics in nuclear, high-energy, and astrophysics, and across a dynamic range from hundreds of keV to many GeV. The scientific program would include observations of low-and high-energy solar neutrinos, determination of neutrino mass ordering and measurement of the neutrino CP-violating phase δ, observations of diffuse supernova neutrinos and neutrinos from a supernova burst, sensitive searches for nucleon decay and, ultimately, a search for neutrinoless double beta decay, with sensitivity reaching the normal ordering regime of neutrino mass phase space. This paper describes Theia, a detector design that incorporates these new technologies in a practical and affordable way to accomplish the science goals described above.

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Section: Photodetectionmentioning

confidence: 99%

Theia: an advanced optical neutrino detector

et al. 2020

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“…As large-scale neutrino detectors become ever larger, photon coverage becomes higher, and photon sensor technology becomes more complex with devices like the ARAPUCA [51], the dichroicon [20], or distributed imaging [50], a major bottleneck in both simulation and reconstruction of physics events is the propagation of photons through the detector geometry. Originally created for the water Cherenkov option for the LBNE experiment, a fast photon ray-tracer was developed by Stan Seibert and Anthony LaTorre [52] that improved photon simulation speeds by a factor of 200 over what GEANT4 itself could do.…”

Section: B Chromamentioning

confidence: 99%

Future Advances in Photon-Based Neutrino Detectors: A SNOWMASS White Paper

Klein¹,

Akindele²,

Bernstein³

et al. 2022

Preprint

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“…Substantial work has been dedicated to realizing this concept, both experimentally (218)(219)(220)(221)(222) and in the development of new analysis tools to leverage and enhance this simultaneous detection for large detectors (223)(224)(225)(226)(227)(228)(229).…”

Section: Real-time Detectorsmentioning

confidence: 99%

The Future of Solar Neutrinos

Gann

Zuber

Bemmerer

et al. 2021

Annu. Rev. Nucl. Part. Sci.

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In this article we review the current state of the field of solar neutrinos, including flavor oscillations, nonstandard effects, solar models, cross section measurements, and the broad experimental program thus motivated and enabled. We describe the historical discoveries that contributed to current knowledge, and define critical open questions to be addressed in the next decade. We discuss standard solar models, including uncertainties and problems related to the solar composition, and review experimental and model solar neutrino fluxes, including future prospects. We review the state of the art of the nuclear reaction data relevant for solar fusion in the proton–proton chain and carbon–nitrogen–oxygen cycle. Finally, we review the current and future experimental programs that can address outstanding questions in this field. Expected final online publication date for the Annual Review of Nuclear and Particle Science, Volume 71 is September 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

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Distributed imaging for liquid scintillation detectors

Cited by 13 publications

References 20 publications

Theia: an advanced optical neutrino detector

Theia: an advanced optical neutrino detector

Future Advances in Photon-Based Neutrino Detectors: A SNOWMASS White Paper

The Future of Solar Neutrinos

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