Co-financiado por:
Nome
Neutrinoless double beta decay search with the SNO+ experiment
Código
PTDC/FIS-PAR/2679/2021
Entidade Beneficiária
LIP - Laboratório de Instrumentação e Física Experimental de Partículas
Sumário do Projecto
The discovery of neutrino oscillations (Nobel Prize 2015) has proven that neutrinos do have mass, but we still do not understand what generates that mass. For all elementary charged fermions, interaction of the Higgs field with the Dirac fields of each particle appears to be the relevant mechanism. For neutrinos another possibility exists. Since they are the only elementary neutral fermions, they can be Majorana particles and their mass can be generated in different ways.The understanding of this question has far-reaching implications in both Particle Physics and Cosmology. If neutrinos are Majorana particles, this would certainly imply new physics and new symmetries beyond the Standard Model of Particle Physics, and would support the idea of generation of the matter/antimatter asymmetry in the early Universe through charge-parity (CP) violation in the leptonic sector. Experimentally, the Majorana nature of neutrinos can be tested by searching for the neutrinoless mode of the extremely rare double beta decays, that are known to occur for several isotopes in the standard mode with two neutrino emission. The search for neutrinoless double beta decay (0nbb) is therefore a high priority of the global particle physics program, and is also the main goal of the SNO+ experiment and this proposal.In order to search for 0nbb, with half-lifes larger than 10^25 yrs, experiments need to have extremely low levels of background and employ massive quantities of a candidate decaying isotope.SNO+ is an underground, low energy and low background experiment using 780 tons of liquid scintillator contained in an acrylic sphere, shielded by ultra-pure water and viewed by an array of photomultiplier tubes (PMTs). SNO+ will search for 0nbb decay by loading ton-scale quantities of the Te130 0nbb isotope in the liquid scintillator, benefiting from its large natural abundance (34%, the largest of the 0nbb isotopes) which doesn’t require enrichment, a Q-value above most of the natural radioactivity, and relatively large nuclear matrix elements that make the 0nbb more favourable to be observed. As of February 2021, the detector was filled with about 740 tons (95% of the total mass) of liquid scintillator and the Te purification plant had been fully installed underground. The isotope loading is expected to be complete by summer 2023, followed by 5 years of data taking.The primary goal of this research plan is to observe indications of the neutrinoless double beta decay of Te130 or establish a competitive limit for its half-life, with the initial SNO+ data. This will be the first time that the scintillator loading technique will be employed with Te130, laying the groundwork towards the full SNO+ Te loading analysis and the next generation of experiments aiming at the normal hierarchy of neutrino masses.In order to reach these physics goals we will provide a thorough characterisation of the detector response and backgrounds impacting both the two-neutrino (2nbb) and 0nbb decay signals by improving the existing methods for particle identification and by developing new advanced algorithms for event classification.We will focus on identifying decays and reactions in the scintillator volume that can fall in the energy region where the signal is expected, their time evolution and spatial non- uniformities. We will track any potential source of contamination, such as radon ingress, leaching off the vessel surface, and muon induced events. Additionally, we will develop algorithms to separate the 0nbb signal from background events based on directionality - a characteristic of solar neutrinos - , and multiple scattering - a signature of gammas from external sources.This research plan will lead to the publication of the first 0nbb decay search results with Tellurium and the loaded scintillator technique -- a high impact outcome in itself -- and to the development of techniques and capabilities essential for the next generation of experiments.This program builds on the LIP neutrino physics group's long standing experience in 0nbb decay searches, event reconstruction algorithms and background characterisation studies, both within the context of SNO+ and other 0nbb experiments.
Suporte sob
Reforçar a investigação, o desenvolvimento tecnológico e a inovação
Região de Intervenção
...
Financiamento
Custo total elegível
€ 231,005.00
Apoio financeiro da UE
Financiamento p/ LIP
€ 0.00
€ 231,005.00
Apoio financeiro público Nacional
€ 231.005¤
Datas
Aprovação
2021-10-15
Início
2021-12-01
Fim
2025-08-31
Reconhecimentos
Versão Extensa: Este trabalho é financiado por fundos nacionais através da FCT - Fundação para a Ciência e a Tecnologia, I.P., no âmbito do projeto PTDC/FIS-PAR/2679/2021
Versão Resumida: OE,FCT-Portugal, PTDC/FIS-PAR/2679/2021
Publicações
Event-by-Event Direction Reconstruction of Solar Neutrinos in a High Light-Yield Liquid Scintillator | Article in international journal (with direct contribution from team) | submitted |
Evidence of antineutrinos from distant reactors using pure water at SNO+ | Article in international journal (with direct contribution from team) | published |
Improved search for invisible modes of nucleon decay in water with the SNO+ detector | Article in international journal (with direct contribution from team) | published |
Initial measurement of reactor antineutrino oscillation at SNO+ | Article in international journal (with direct contribution from team) | submitted |
Neutrinoless double-beta decay search with SNO+ | International Conference Proceedings | published |
Apresentações
Antineutrino measurements in SNO+ | Oral presentation in international conference |
Antineutrino measurements in the SNO+ phase | Seminar |
Deconstructing biases: connencting scientific and cultural knowledge. Bias in science: reflections from a neutrino physicist | Outreach seminar |
From reactor and solar neutrinos to neutrinoless double-beta decay: the wide physics range of the SNO+ experiment | Seminar |
From reactor and solar neutrinos to neutrinoless double-beta decay: the wide physics range of the SNO+ experiment | Seminar |
Neutrino Science 1 | Oral presentation in advanced training events |
Neutrino Science 2 | Oral presentation in advanced training events |
Neutrino Science 3 | Oral presentation in advanced training events |
Neutrino Science 4 | Oral presentation in advanced training events |
Neutrino Science 5 | Oral presentation in advanced training events |
Neutrinoless double beta decay: status and prospects of searches with liquid scintillator detectors | Oral presentation in international conference |
Neutrinoless double-beta decay search with SNO+ | Oral presentation in international conference |
Neutrinos and Dark Matter | Oral presentation in national or international meeting |
Reactor Antineutrinos in SNO+ | Seminar |
SNO+ Experiment Update | Oral presentation in national or international meeting |
Solar Neutrinos: Recent Results and Prospects | Oral presentation in international conference |
The liquid scintillator phase of SNO+: current status and future prospects | Seminar |
Teses
Measurement of the 130 Te Two-Neutrino Double Beta Decay Half-life with the SNO+ Experiment | ||
Neutrinoless double-beta decay search with SNO+: Enhancing sensitivity through improved event reconstruction using Machine Learning |
Equipa
Amélia Arminda Teixeira Maio |
Ana Sofia Carpinteiro Inácio |
Beymar Javier Quenallata Surco |
Fernando José de Carvalho Barão |
Joan Alejandro Dos Santos Kladnik |
José Carvalho Maneira |
Nuno Filipe Fiuza de Barros |
Sofia Andringa Dias |
Valentina Lozza |