Sterile Neutrino Constraints from the STEREO Experiment with 66 Days of Reactor-On Data

Almazán, H.; Sanchez, P. del Amo; Bernard, L.; Blanchet, Adrien; Bonhomme, A.; Buck, C.; Favier, Jean; Haser, J.; Hélaine, V.; Kandzia, F.; Kox, S.; Lamblin, J.; Letourneau, A.; Lhuillier, D.; Lindner, M.; Manzanillas, L.; Materna, T.; Minotti, A.; Montanet, F.; Pessard, H.; Réal, J. S.; Roca, C.; Salagnac, T.; Schoppmann, S.; Sergeyeva, V.; Söldner, T.; Stutz, A.; Zsoldos, S.

doi:10.1103/physrevlett.121.161801

Cited by 100 publications

(93 citation statements)

References 56 publications

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“…We begin with PROSPECT and STEREO, which have produced early results [63][64][65], but not, at present, final analyses. These experiments were designed in the first half of the decade to conclusively probe the RAA as presented in Ref.…”

Section: Introductionmentioning

confidence: 99%

Reevaluating reactor antineutrino anomalies with updated flux predictions

Berryman

2020

Phys. Rev. D

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Hints for the existence of a sterile neutrino at nuclear reactors are reexamined using two updated predictions for the fluxes of antineutrinos produced in fissions. These new predictions diverge in their preference for the rate deficit anomaly, relative to previous analyses, but the anomaly in the ratios of measured antineutrino spectra persists. We comment on upcoming experiments and their ability to probe the preferred region of the sterile-neutrino parameter space in the electron neutrino disappearance channel. arXiv:1909.09267v1 [hep-ph]

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Section: Introductionmentioning

confidence: 99%

Reevaluating reactor antineutrino anomalies with updated flux predictions

Berryman

2020

Phys. Rev. D

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“…All these components are known for low absorption of near UV light, high radiopurity, suitable safety properties, chemical inertness and moderate costs. The good performance of a LAB and PPO combination was demonstrated and studied in several multi-ton scale neutrino projects [2][3][4][5][6][7]. The paraffin wax is chemically similar to the n-paraffins also used in the LS of different neutrino detectors [2,9].…”

Section: Scintillator Design and Productionmentioning

confidence: 99%

“…Many applications in the field of neutrino physics call for metal loading of the organic scintillator. Some examples are the gadolinium (Gd) loading to detect neutrons after the inverse beta decay of antineutrinos [2][3][4][5], boron (B) loading in active veto systems [18], tellurium (Te)/neodymium (Nd) loading for neutrinoless double beta decay experiments [19] or indium (In) loading for solar neutrino detection [20]. Metal loading in the NoWaSH approach can be similar as for other LS.…”

Section: Boron Loadingmentioning

confidence: 99%

Novel opaque scintillator for neutrino detection

Buck

Gramlich²,

Schoppmann

2019

J. Inst.

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A: There is rising interest in organic scintillators with low scattering length for future neutrino detectors. Therefore, a new scintillator system was developed based on admixtures of paraffin wax in linear alkyl benzene. The transparency and viscosity of this gel-like material can be tuned by temperature adjustment. Whereas it is a colorless transparent liquid at temperatures around 40 • C, it has a milky wax structure below 20 • C. The production and properties of such a scintillator as well as its advantages compared to transparent liquids are described.

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“…Also an excess of events, in energy region ∼5 MeV, observed in the prompt event spectrum of the reactor ν e induced inverse beta decays (IBD), has opened up new avenues for further studies in reactor based ν e [3][4][5]. Various experiments, using moderate scale (few tonnes) detector, are being proposed or taking data at very short baselines to further understand the properties associated with the reactor anti-neutrinos [6][7][8][9]. The Indian Scintillator Matrix for Reactor Anti-Neutrinos (ISMRAN) experiment is one such detector consisting of plastic scintillator (PS) bars in an array forming an active detection volume of 1.0 ton by weight [10].…”

Section: Introductionmentioning

confidence: 99%

Machine learning technique to improve anti-neutrino detection efficiency for the ISMRAN experiment

et al. 2020

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A: The Indian Scintillator Matrix for Reactor Anti-Neutrino detection -ISMRAN experiment aims to detect electron anti-neutrinos (ν e ) emitted from a reactor via inverse beta decay reaction (IBD). The setup, consisting of 1 ton segmented Gadolinium foil wrapped plastic scintillator array, is planned for remote reactor monitoring and sterile neutrino search. The detection of prompt positron and delayed neutron from IBD will provide the signature of ν e event in ISMRAN. The number of segments with energy deposit (N bars ) and sum total of these deposited energies are used as discriminants for identifying prompt positron event and delayed neutron capture event. However, a simple cut based selection of above variables leads to a low ν e signal detection efficiency due to overlapping region of N bars and sum energy for the prompt and delayed events. Multivariate analysis (MVA) tools, employing variables suitably tuned for discrimination, can be useful in such scenarios. In this work we report the results from artificial neural network classifierthe multilayer perceptron (MLP), particularly the Bayesian extension -MLPBNN, to achieve better signal detection efficiencies with reasonable background rejection. The neural network response is used to distinguish prompt positron events from delayed neutron capture events on Hydrogen, Gadolinium nucleus, and from a typical reactor γ-ray background. A prompt signal efficiency of ∼91% with a reasonable background rejection of ∼73% is achievable with the MLPBNN classifier for the ISMRAN experiment.

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Sterile Neutrino Constraints from the STEREO Experiment with 66 Days of Reactor-On Data

Cited by 100 publications

References 56 publications

Reevaluating reactor antineutrino anomalies with updated flux predictions

Reevaluating reactor antineutrino anomalies with updated flux predictions

Novel opaque scintillator for neutrino detection

Machine learning technique to improve anti-neutrino detection efficiency for the ISMRAN experiment

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