Boosting background suppression in the NEXT experiment through Richardson-Lucy deconvolution

Simón, A.; Ifergan, Y.; Redwine, A. B.; Weiss-Babai, R.; Arazi, L.; Adams, C.; Almazán, H.; Álvarez, V.; Aparicio, B.; Aranburu, A.I.; Arnquist, I. J.; Azevedo, C.D.R.; Bailey, K.; Ballester, F.; Benlloch-Rodríguez, J.M.; Borges, F.I.G.M.; Byrnes, N.; Cárcel, S.; Carrión, J.V.; Cebrián, S.; Church, E.; Conde, C.A.N.; Contreras, T.; Cossío, Fernando P.; Denisenko, A. A.; Díaz, G. A.; Díaz, J.; Escada, J.; Esteve, R.; Felkai, R.; Fernandes, L. M. P.; Ferrario, P.; Ferreira, A. L.; Foss, Frank W.; Freitas, E.D.C.; Freixa, Zoraida; Generowicz, J.; Goldschmidt, A.; Gómez-Cadenas, J.J.; Gonzalez, R. C.; González-Díaz, D.; Gosh, S.; Guénette, R.; Gutiérrez, Rafael; Haefner, J.; Hafidi, K.; Hauptman, J. M.; Henriques, C. A. O.; Morata, J. A. Hernando; Herrero, Pablo; Herrero, V.; Ho, Johnny C.; Jones, Ben; Kekic, M.; Labarga, L.; Laing, A.; Lebrun, P.; López-March, N.; Losada, M.; Mano, R.D.P.; Martín-Albo, J.; Martínez, A.; Martínez-Vara, M.; Martínez-Lema, G.; McDonald, A. D.; Meziani, Z. E.; Monrabal, F.; Monteiro, C. M. B.; Mora, Francisco; Vidal, J. Muñoz; Newhouse, C.; Novella, P.; Nygren, D. R.; Oblak, E.; Odriozola-Gimeno, M.; Palmeiro, B.; Para, A.; Pérez, Javier Laso; Querol, M.; Renner, J.; Ripoll, L.; Rivilla, Iván; García, Y. Rodríguez; Rodriguez, J.; Rogero, Celia; Rogers, L.; Romeo, B.; Romo-Luque, C.; Santos, F.P.; Santos, J. M. F. dos; Sorel, M.; Stanford, C.; Teixeira, J. M. R.; Thapa, Pawan; Toledo, J.F.; Torrent, J.; Usón, A.; Veloso, J.F.C.A.; Vuong, T.T.; Webb, R.; White, James T.; Woodruff, K.; Yahlali, N.

doi:10.1007/jhep07(2021)146

Cited by 6 publications

(10 citation statements)

References 40 publications

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“…The ratio of the signal efficiency over the square root of the background acceptance ranges from ≈2.3 to ≈3.1 for events between 1 and 3 MeV energy, consistent with Ref. [15]. According to this selection, the top and bottom panels of Fig.…”

Section: Event Reconstruction and Selectionsupporting

confidence: 85%

“…The deconvolved 3D hits are then grouped into volume elements of (5 mm) 3 , which are used to build tracks following the connectivity criteria established by a breadth-first search algorithm [16]. The energies of the endpoints of each track, hereafter "blobs," are defined by integrating the energy of the hits contained within spheres of 18 mm in radius centered in the identified extremes [15]. Figure 3 shows examples of two observed tracks of 1.7 MeV.…”

Section: Event Reconstruction and Selectionmentioning

confidence: 99%

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Measurement of the Xe136 two-neutrino double- β -decay half-life via direct background subtraction in NEXT

Novella¹,

Sorel²,

Usón³

2022

Phys. Rev. C

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We report a measurement of the half-life of the 136 Xe two-neutrino double-β decay performed with a novel direct-background-subtraction technique. The analysis relies on the data collected with the NEXT-White detector operated with 136 Xe-enriched and 136 Xe-depleted xenon, as well as on the topology of double-electron tracks. With a fiducial mass of only 3.5 kg of Xe, a half-life of 2.34 +0.80 −0.46 (stat) +0.30 −0.17 (sys) × 10 21 yr is derived from the background-subtracted energy spectrum. The presented technique demonstrates the feasibility of unique background-model-independent neutrinoless double-β-decay searches.

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Section: Event Reconstruction and Selectionsupporting

confidence: 85%

Section: Event Reconstruction and Selectionmentioning

confidence: 99%

Measurement of the Xe136 two-neutrino double- β -decay half-life via direct background subtraction in NEXT

Novella¹,

Sorel²,

Usón³

2022

Phys. Rev. C

Self Cite

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“…Tracking information is obtained from a SiPM array at the anode, while PMTs at the cathode provide optimal energy resolution. NEXT-White (Monrabal et al, 2018), a proof-of-principle detector with 5 kg of Xe at 10 bar, demonstrated an energy resolution of σ = 10 keV at Q ββ (Renner et al, 2019), and tracking performance capable of discriminating sin-gle and double electron track events, retaining 57% of signal events while rejecting background by a factor of 27 (Simón et al, 2020). A second stage, NEXT-100 (Alvarez et al, 2012;Martín-Albo et al, 2016), with a pressure of 15 bar and containing 87 kg of 136 Xe, is currently under construction.…”

Section: Xenon Time Projection Chambersmentioning

confidence: 99%

Toward the discovery of matter creation with neutrinoless double-beta decay

Agostini¹,

Benato²,

Detwiler³

et al. 2022

Preprint

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The discovery of neutrinoless double-beta decay could soon be within reach. This hypothetical ultra-rare nuclear decay is a portal to new physics beyond the Standard Model. Its observation would constitute the discovery of a matter-creating process, corroborating leading theories of why the universe contains more matter than antimatter, and how the forces unify at high energy scales. It would also prove that neutrinos and antineutrinos are not two distinct particles, but can transform into each other, generating their own mass in the process. The recognition that neutrinos are not massless necessitates an explanation and has boosted interest in neutrinoless double-beta decay. The field is now at a turning point. A new round of experiments is currently being prepared for the next decade to cover an important region of parameter space. Advancements in nuclear theory are laying the groundwork to connect the nuclear decay with the underlying new physics. Meanwhile, the particle theory landscape continues to find new motivations for neutrinos to be their own antiparticle. This review brings together the experimental, nuclear theory, and particle theory aspects connected to neutrinoless double-beta decay, to explore the path toward -and beyond -its discovery.

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“…On the other hand, for high-energy events, the threshold is increased to 10 photoelectrons per 1 µs time slice. This value was identified as the optimal threshold for track reconstruction [ 23 ]. Still, given the non-reversibility nature of lossy compression, a heavily conservative ZS configuration was chosen for standard data-taking.…”

Section: Next Experiments Data Compression Studymentioning

confidence: 99%

Data Compression in the NEXT-100 Data Acquisition System

Bosch

Ponce

Estévez

et al. 2022

Sensors

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NEXT collaboration detectors are based on energy measured by an array of photomultipliers (PMT) and topological event filtering based on an array of silicon photomultipliers (SiPMs). The readout of the PMT sensors for low-frequency noise effects and detector safety issues requires a grounded cathode connection that makes the readout AC-couple with variations in the signal baseline. Strict detector requirements of energy resolution better than 1% FWHM require a precise baseline reconstruction that is performed offline for data analysis and detector performance characterization. Baseline variations make it inefficient to apply traditional lossy data compression techniques, such as zero-suppression, that help to minimize data throughput and, therefore, the dead time of the system. However, for the readout of the SiPM sensors with less demanding requirements in terms of accuracy, a traditional zero-suppression is currently applied with a configuration that allows for a compression ratio of around 71%. The third stage in the NEXT detectors program, the NEXT-100 detector, is a 100 kg detector that instruments approximately five times more PMT sensors and twice the number of SiPM sensors than its predecessor, the NEXT-White detector, putting more pressure in the DAQ throughput, expected to be over 900 MB/s with the current configuration, which will worsen the dead time of the acquisition data system. This paper describes the data compression techniques applied to the sensor data in the NEXT-100 detector, which reduces data throughput and minimizes dead time while maintaining the event rate to the level of its predecessor, around 50 Hz.

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Boosting background suppression in the NEXT experiment through Richardson-Lucy deconvolution

Cited by 6 publications

References 40 publications

Measurement of the Xe136 two-neutrino double- β -decay half-life via direct background subtraction in NEXT

Measurement of the Xe136 two-neutrino double- β -decay half-life via direct background subtraction in NEXT

Toward the discovery of matter creation with neutrinoless double-beta decay

Data Compression in the NEXT-100 Data Acquisition System

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