Radioactivity control strategy for the JUNO detector

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doi:10.1007/jhep11(2021)102

Cited by 20 publications

(29 citation statements)

References 34 publications

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“…Since then, the total reactor thermal power available to JUNO decreased of ∼26% (from 35.8 GW to 26.6 GW) because only two of the planned four Taishan reactors have been built; moreover, the expected muon flux is now ∼33% higher (from 3 to 4 Hz) because of the shallower location of the JUNO experimental hall due to the underground water problem. On the other hand, we expect a ∼3% improvement of the detector energy resolution (from 3% to 2.9% at 1 MeV), thanks to the higher photon detection efficiency of the LPMTs, to an improved understanding of the PMT optical model, and to a more accurate simulation of the detector geometry; moreover, we expect a ∼10% improvement of the muon veto efficiency (from 83% to 91.6%), and we have more realistic estimations of the expected backgrounds from the detector materials [8]. Finally, we expect an improved reactor spectral shape uncertainty thanks to the combined analysis with the Taishan Antineutrino Observatory (TAO) [11], a 1 ton LS satellite detector placed at 30 m distance from one of the Taishan reactor cores to measure the unoscillated antineutrino flux with high precision.…”

Section: Updates On Juno Physics Sensitivitymentioning

confidence: 93%

“…Due to its dimensions, it is divided into 265 panels which are produced separately at the company and bonded onsite. There are very stringent requirements on the light transparency of the acrylic, which must be higher than 96% to reach the target energy resolution of JUNO, and on its radiopurity: the concentration of each of the natural contaminants ( 238 U, 232 Th, 40 K) must be below 1 ppt to keep the accidental background rate within JUNO requirements [8].…”

Section: Juno Detector Construction Progressmentioning

confidence: 99%

“…The LS is a Linear Alkyl Benzene (LAB) solvent mixed with 2.5 g/L PPO fluor and 3 mg/L bis-MSB wavelength shifter. To fulfil JUNO demanding requirements, it must have a very high light yield (> 1345 p.e./MeV), a long attenuation length (> 20 m), and extremely high radiopurity (< 10 −17 g/g for 238 U and 232 Th, < 10 −18 g/g for 40 K, < 10 −24 g/g for 210 Pb) [8]. An industrial scale purification process was designed, and is under construction at the JUNO site.…”

Section: Juno Detector Construction Progressmentioning

confidence: 99%

“…8 B solar neutrinos will be measured by JUNO via elastic scattering on electrons with the unprecedented energy threshold of 2 MeV. In addition, by exploiting the 200 t of 13 C of the LS, JUNO will detect 8 B neutrinos also via charged current and neutral current interactions on 13 C, and thus will study 8 B neutrinos in a model independent way. The sensitivity of JUNO to lower energy solar neutrinos (i.e.…”

Section: Updates On Juno Physics Sensitivitymentioning

confidence: 99%

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Jiangmen Underground Neutrino Observatory (JUNO): on the way to physics data

Sisti¹

2023

Proceedings of Neutrino Oscillation Workshop — PoS(NOW2022)

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The Jiangmen Underground Neutrino Observatory (JUNO) is a 20 kton liquid scintillator experiment under construction in South China, at Kaiping, Jiangmen, Guandong province. Its primary physics goals are the determination of the neutrino mass ordering and the precise determination of the neutrino oscillation parameters by means of the accurate measurement of the oscillated spectrum of antineutrinos emitted by two reactor complexes, Taishan and Yangjiang, located at 53 km distance from the experiment. Given its dimensions and anticipated performance, JUNO has a very rich physics program which includes the study of neutrinos from the Sun, the Earth, the Galaxy, and eventually from Supernovae, and will give important contributions to the study of new physics processes. The JUNO collaboration plans to finish the detector construction by the end of 2023. In this paper I review the detector progress and the updated sensitivities on the main physics channels.

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Section: Updates On Juno Physics Sensitivitymentioning

confidence: 93%

Section: Juno Detector Construction Progressmentioning

confidence: 99%

Section: Juno Detector Construction Progressmentioning

confidence: 99%

Section: Updates On Juno Physics Sensitivitymentioning

confidence: 99%

See 2 more Smart Citations

Jiangmen Underground Neutrino Observatory (JUNO): on the way to physics data

Sisti¹

2023

Proceedings of Neutrino Oscillation Workshop — PoS(NOW2022)

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“…The gamma radiation occurring during the reaction could be thus measured by a HPGe detector. NAA can achieve substantially greater sensitivity than direct γ ray counting, typically at ppt and sub-ppt levels [26].…”

Section: Jhep06(2022)147mentioning

confidence: 99%

Low radioactive material screening and background control for the PandaX-4T experiment

Qian

Abdukerim

et al. 2022

J. High Energ. Phys.

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PandaX-4T is a ton-scale dark matter direct detection experiment using a dual-phase TPC technique at the China Jinping Underground Laboratory. Various ultra-low background technologies have been developed and applied to material screening for PandaX-4T, including HPGe gamma spectroscopy, ICP-MS, NAA, radon emanation measurement system, krypton assay station, and alpha detection system. Low background materials were selected to assemble the detector. Surface treatment procedures were investigated to further suppress radioactive background. Combining measured results and Monte Carlo simulation, the total material background rates of PandaX-4T in the energy region of 1–25 keVee are estimated to be (9.9 ± 1.9) × 10−3 mDRU for electron recoil and (2.8 ± 0.6) × 10−4 mDRU for nuclear recoil. In addition, natKr in the detector is estimated to be < 8 ppt.

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Towards a sub-percent precision measurement of sin2 θ13 with reactor antineutrinos

Zhang

Cao

2023

J. High Energ. Phys.

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Measuring the neutrino mixing parameter sin2θ13 to the sub-percent precision level could be necessary in the next ten years for the precision unitary test of the PMNS matrix. In this work, we discuss the possibility of such a measurement with reactor antineutrinos. We find that a single liquid scintillator detector on a reasonable scale could achieve the goal. We propose to install a detector of ∼ 10% energy resolution at about 2.0 km from the reactors with a JUNO-like overburden. The integrated luminosity requirement is about 150 kton · GW · year, corresponding to 4 years’ operation of a 4 kton detector near a reactor complex of 9.2 GW thermal power like Taishan reactor. Unlike the previous θ13 experiments with identical near and far detectors, which can suppress the systematics especially the rate uncertainty by the near-far relative measurement and the optimal baseline is at the first oscillation maximum of about 1.8 km, a single-detector measurement prefers to offset the baseline from the oscillation maximum. At low statistics ≲ 10 kton · GW · year, the rate uncertainty dominates the systematics, and the optimal baseline is about 1.3 km. At higher statistics, the spectral shape uncertainty becomes dominant, and the optimal baseline shifts to about 2.0 km. The optimal baseline keeps being ∼ 2.0 km for an integrated luminosity up to 106 kton · GW · year. Impacts of other factors on the precision sin2θ13 measurement are also discussed. We have assumed that the TAO experiment will improve our understanding of the spectral shape uncertainty, which gives the highest precision measurement of reactor antineutrino spectrum for neutrino energy in the range of 3–6 MeV. We find that the optimal baseline is ∼ 2.9 km with a flat input spectral shape uncertainty provided by the future summation or conversion methods’ prediction. The shape uncertainty would be the bottleneck of the sin2θ13 precision measurement. The sin2θ13 precision is not sensitive to the detector energy resolution and the precision of other oscillation parameters.

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Radioactivity control strategy for the JUNO detector

Cited by 20 publications

References 34 publications

Jiangmen Underground Neutrino Observatory (JUNO): on the way to physics data

Jiangmen Underground Neutrino Observatory (JUNO): on the way to physics data

Low radioactive material screening and background control for the PandaX-4T experiment

Towards a sub-percent precision measurement of sin2 θ13 with reactor antineutrinos

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