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Abstract
Several anomalies in the neutrino sector are pointing towards the existence of a new (sterile) neutrino state with a mass around 1~eV.
The SoLid experiment is located at the SCK∙CEN BR2 research reactor in Belgium and will investigate this possibility.
Using the large flux of antineutrinos generated in the reactor, it will collect a high statistics sample of Inverse Beta Decay (IBD) events.
These will be used to study the energy and distance dependence of the neutrino flux, which in turn will provide unambiguous support or reject the evidence of sterile neutrinos being the cause of these anomalies.
The measurement is challenging as one has to operate a detector very close to the high radiation environment of a nuclear reactor and on the surface with little overburden to shield against cosmic rays.
SoLid is employing a new technology combining PVT (cubes of 5×5×5 cm3) and 6LiF:ZnS(Ag) scintillators (sheets ∼250 μm thickness) to face these challenges.
The highly segmented detector is read out by a network of wavelength shifting fibers and SiPMs, which allows for a precise localization of the IBD reaction products.
Neutrons captured in the 6Li can be easily separated from electromagnetic particles (e+,γ) which are absorbed in the PVT, due to the different response of the respective scintillators.
The 1.6 tons detector was installed towards the end of 2017 and is taking date since early 2018.
We will describe the detector design, the experimental setup at BR2 and the detection principle. This will be followed by a first look at the data.
The SoLid experiment is located at the SCK∙CEN BR2 research reactor in Belgium and will investigate this possibility.
Using the large flux of antineutrinos generated in the reactor, it will collect a high statistics sample of Inverse Beta Decay (IBD) events.
These will be used to study the energy and distance dependence of the neutrino flux, which in turn will provide unambiguous support or reject the evidence of sterile neutrinos being the cause of these anomalies.
The measurement is challenging as one has to operate a detector very close to the high radiation environment of a nuclear reactor and on the surface with little overburden to shield against cosmic rays.
SoLid is employing a new technology combining PVT (cubes of 5×5×5 cm3) and 6LiF:ZnS(Ag) scintillators (sheets ∼250 μm thickness) to face these challenges.
The highly segmented detector is read out by a network of wavelength shifting fibers and SiPMs, which allows for a precise localization of the IBD reaction products.
Neutrons captured in the 6Li can be easily separated from electromagnetic particles (e+,γ) which are absorbed in the PVT, due to the different response of the respective scintillators.
The 1.6 tons detector was installed towards the end of 2017 and is taking date since early 2018.
We will describe the detector design, the experimental setup at BR2 and the detection principle. This will be followed by a first look at the data.
| Original language | English |
|---|---|
| Article number | 067 |
| Number of pages <span style="color:red"p> <font size="1.5"> ✽ </span> </font> | 4 |
| Journal | PoS Proceedings of Science |
| Volume | 337 |
| DOIs | |
| Publication status | Published - 24 Apr 2019 |
| Event | Neutrino Oscillation Workshop - INFN, Otsuni, Italy Duration: 9 Sep 2018 → 16 Sep 2018 http://www.ba.infn.it/~now/now2018/index.html |
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Dive into the research topics of 'SoLid: Search for oscillations with a 6Li detector'. Together they form a unique fingerprint.Projects
- 1 Finished
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SRP8: Strategic Research Programme: High-Energy Physics at the VUB
D'Hondt, J., Van Eijndhoven, N., Craps, B. & Buitink, S.
1/11/12 → 31/10/24
Project: Fundamental