Prospects for beyond the Standard Model physics searches at the Deep Underground Neutrino Experiment

Abi, B.; Acciarri, R.; Acero, M. A.; Adamov, G.; Adams, D. L.; Adinolfi, M.; Ahmad, Zahid; Ahmed, Jamal; Alion, T.; Monsalve, S. Alonso; Alt, C.; Anderson, J.; Andreopoulos, C.; Andrews, M.; Andrianala, F.; Andringa, S.; Ankowski, Artur M.; Antonova, M.; Antusch, Stefan; Aranda-Fernandez, A.; Ariga, A.; Arnold, L.; Arroyave, M. A.; Asaadi, J.; Aurisano, A.; Aushev, V.; Autiero, D.; Azfar, F.; Back, H. O.; Back, J. J.; Backhouse, C.; Baesso, P.; Bagby, L.; Bajou, R.; Balasubramanian, S.; Baldi, Pierre; Bambah, Bindu A.; Barão, F.; Barenboim, Gabriela; Barker, G. J.; Barkhouse, W. A.; Barnes, C.; Barr, G.; Monarca, J. Barranco; Barros, N.; Barrow, J. L.; Bashyal, A.; Basque, V.; Bay, F.; Alba, J. L. Bazo; Beacom, J. F.; Bechetoille, E.; Behera, B. R.; Bellantoni, L.; Bellettini, G.; Bellini, Vincenzo; Beltramello, O.; Belver, D.; Benekos, N.; Neves, F.; Berger, Joshua; Berkman, S.; Bernardini, P.; Berner, R. M.; Berns, H.; Bertolucci, S.; Betancourt, M.; Bezawada, Y.; Bhattacharjee, M.; Bhuyan, B.; Biagi, S.; Bian, J. M.; Biassoni, M.; Biery, K.; Bilki, B.; Bishai, M.; Bitadze, A.; Blake, A.; Siffert, B. Blanco; Blaszczyk, F. d. M.; Blazey, G.; Blucher, E.; Boissevain, J. G.; Bolognesi, S.; Bolton, T.; Bonesini, M.; Bongrand, M.; Bonini, F.; Booth, Alexander; Booth, C.N.; Bordoni, S.; Borkum, A.; Boschi, T.; Bostan, N.; Bour, P.; Boyd, S. B.; Boyden, D.; Braciník, J.; Braga, D.; Brailsford, D.; Brandt, A.; Bremer, J.; Brew, C.; Brianne, Eldwan; Brice, S. J.; Brizzolari, C.; Bromberg, C.; Brooijmans, G.; Brooke, J. J.; Bross, A.; Brunetti, G.; Buchanan, N. J.; Budd, H. S.; Caiulo, D.; Calafiura, P.; Calcutt, J.; Călin, M.; Calvez, S.; Calvo, E.; Camilleri, L.; Caminata, A.; Campanelli, M.; Caratelli, D.; Carini, G.; Carlus, B.; Carniti, P.; Terrazas, I. Caro; Carranza, H.; Castillo, A.; Castromonte, C.; Cattadori, C.; Cavalier, F.; Cavanna, F.; Centro, S.; Cerati, G. B.; Cervelli, A.; Villanueva, A. Cervera; Chalifour, M.; Chang, C.; Chardonnet, Etienne; Chatterjee, A.; Chattopadhyay, S.; Chaves, J.; Chen, H.; Chen, M.; Chen, Y.; Cherdack, D.; Chi, C.Y.; Childress, S.; Chiriacescu, A.; Cho, K.; Choubey, Sandhya; Christensen, A.; Christian, David; Christodoulou, G.; Church, E.; Clarke, P. E. L.; Coan, T. E.; Cocco, A. G.; Coelho, J. A. B.; Conley, E.; Conrad, J. M.; Convery, M. R.; Corwin, L. A.; Cotte, P.; Cremaldi, L.; Cremonesi, L.; Crespo-Anadón, J. I.; Cristaldo, E.; Cross, R.; Cuesta, C.; Cui, Yanou; Cussans, D.; Dabrowski, M.; Motta, H. da; Peres, L. Da Silva; David, C.; David, Q.; Davies, Gavin; Davini, S.; Dawson, J.; De, K.; Almeida, R. M. de; Debbins, P.; Bonis, I. De; Decowski, M. P.; Gouvêa, André de; Holanda, P. C. de; Astiz, I. L. De Icaza; Deisting, A.; Jong, P. de; Delbart, A.; Delépine, D.; Delgado, M. A. Segura; Dell’Acqua, A.; Lurgio, P. De; Neto, J. R. T. de Mello; DeMuth, D. M.; Dennis, S. R.; Densham, C.; Deptuch, G.; Roeck, A. De; Romeri, Valentina De; Vries, J. Jan de; Dharmapalan, R.; Dias, M.; Díaz, F.; Díaz, Jorge S.; Domizio, S. Di; Giulio, L. Di; Ding, P. F.; Noto, L. Di; Distefano, C.; Diurba, R.; Diwan, M. V.; Djurcic, Z.; Dokania, N.; Dolinski, M. J.; Domine, L.; Douglas, D.; Drielsma, F.; Duchesneau, D.; Duffy, K.; Dunne, P.; Durkin, T.; Duyang, H.; Dvornikov, O.; Dwyer, D. A.; Dyshkant, A.; Eads, M.; Edmunds, D.; Eisch, J.; Emery, S.; Ereditato, A.; Escobar, C. O.; Sanchez, L. Escudero; Evans, Justin J.; Ewart, E.; Ezeribe, A. C.; Fahey, Kevin; Falcone, A.; Farnese, C.; Farzan, Yasaman; Félix, J.; Fernández‐Martínez, E.; Menendez, P. Fernandez; Ferraro, F.; Fields, L.; Filkins, A.; Filthaut, F.; Fitzpatrick, R. S.; Flanagan, W.; Fleming, B. T.; Flight, R.; Fowler, J.; Fox, W.; Franc, J.; Francis, K.; Franco, D.; Freeman, J.; Freestone, J.; Fried, J.; Friedland, Alexander; Fuess, S.; Furic, I. K.; Furmanski, A. P.; Gago, A. M.; Gallagher, H.; Gallego-Ros, A.; Gallice, N.; Galymov, V.; Gamberini, E.; Gamble, T.; Gandhi, Raj; Gandrajula, Reddy Pratap; Gao, Shanshan; García-Gámez, D.; García-Peris, M. Á.; Gardiner, S.; Gastler, D.; Ge, G.; Gelli, B.; Gendotti, A.; Gent, Stephen P.; Ghorbani-Moghaddam, Z.; Gibin, D.; Gil-Botella, I.; Girerd, C.; Giri, A.; Gnani, D.; Gogota, O.; Gold, M.; Gollapinni, S.; Gollwitzer, K.; Gomes, R. A.; Bermeo, L. V. Gomez; Fajardo, L. S. Gomez; Gonnella, F.; Gonzalez-Cuevas, J. A.; Goodman, M. C.; Goodwin, O.; Goswami, Sumanta; Gotti, C.; Goudzovski, E.; Grace, C.; Graham, M. T.; Gramellini, E.; Gran, R.; Granados, E.; Grant, A.; Grant, C.; Gratieri, D.; Green, P.; Green, S.; Greenler, L.; Greenwood, Margaret S.; Greer, J.; Griffith, William C.; Groh, M.; Grudzinski, J.; Grzelak, K.; Gu, W.; Guarino, V. J.; Guénette, R.; Guglielmi, A.; Guo, B.; Guthikonda, K. K.; Gutiérrez, Rafael; Guzowski, P.; Guzzo, M. M.; Gwon, S.; Habig, A.; Hackenburg, A.; Hadavand, H. 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D.; Metcalf, W.; Mewes, Matthew; Meyer, H.; Miao, T.; Michna, Gregory J.; Miedema, T.; Migenda, J.; Milinčić, R.; Miller, William H.; Mills, J.; Milne, Christopher J.; Mineev, O.; Miranda, O. G.; Miryala, Sandeep; Mishra, C. S.; Mishra, S. R.; Mislivec, A.; Mladenov, D.; Mocioiu, I.; Moffat, K.; Moggi, N.; Mohanta, Rukmani; Mohayai, T.; Mokhov, N.; Molina, Jorge; Bueno, L. Molina; Montanari, A.; Montanari, C.; Montanari, D.; Zetina, L. Montaño; Moon, J.; Mooney, M.; Moor, A. F.; Moreno, D.; Morgan, B.; Morris, C.; Mossey, C.; Motuk, E.; Moura, C. A.; Mousseau, J.; Mu, Wei; Mualem, L.; Mueller, J.; Muether, M.; Mufson, S.; Muheim, F.; Muir, A.; Mulhearn, M.; Muramatsu, H.; Murphy, S.; Musser, J.; Nachtman, J.; Nagu, S.; Nalbandyan, M.; Nandakumar, R.; Naples, D.; Narita, S.; Navas-Nicolás, D.; Nayak, N.; Nebot-Guinot, M.; Necib, Lina; Negishi, K.; Nelson, J. K.; Nesbit, J.; Nessi, M.; Newbold, D. M.; Newcomer, M.; Newhart, D.; Nichol, R. J.; Niner, E.; Nishimura, K.; Norman, A.; Norrick, A.; Northrop, R.; Novella, P.; Nowak, J.; Oberling, M.; Campo, A. Olivares Del; Olivier, A.; Onel, Y.; Onishchuk, Y.; Ott, Jordan; Pagani, L.; Pakvasa, Sandip; Palamara, O.; Palestini, S.; Paley, J.; Pallavicini, M.; Palomares, C.; Pantic, E.; Paolone, V.; Papadimitriou, V.; Papaleo, R.; Papanestis, A.; Paramesvaran, S.; Park, J. C.; Parke, Stephen J.; Parsa, Z.; Parvu, M.; Pascoli, Silvia; Pasqualini, L.; Pasternak, J.; Pater, J. R.; Patrick, C.; Patrizii, L.; Patterson, R. B.; Patton, S.; Patzak, T.; Paudel, A.; Paulos, B.; Paulucci, L.; Pavlović, Ž.; Pawloski, G.; Payne, D. J.; Pec, V.; Peeters, S. J. M.; Pénichot, Y.; Pennacchio, E.; Penzo, A.; Peres, O. L. G.; Perry, James; Pershey, D.; Pessina, G.; Petrillo, G.; Petta, C.; Petti, R.; Piastra, F.; Pickering, L.; Pietropaolo, F.; Pillow, Jonathan W.; Pinzino, J.; Plunkett, R.; Poling, R.; Pons, X.; Poonthottathil, N.; Pordes, S.; Potekhin, M.; Potenza, R.; Potukuchi, B.; Pozimski, J.; Pozzato, M.; Prakash, Suprabh; Prakash, T.; Prince, S.; Prior, G.; Pugnère, D.; Qi, K. H.; Qian, X.; Raaf, J. L.; Raboanary, R.; Radeka, V.; Rademacker, J. H.; Radics, B.; Rafique, A.; Raguzin, Е.; Rai, M.; Rajaoalisoa, M.; Rakhno, I.; Rakotondramanana, H. T.; Rakotondravohitra, L.; Ramachers, Y. A.; Rameika, R.; Delgado, M. A. Ramirez; Ramson, B.; Rappoldi, A.; Raselli, G.L.; Ratoff, P. N.; Ravat, S.; Razafinime, H.; Réal, J. S.; Rebel, B.; Redondo, D.; Reggiani-Guzzo, M.; Rehak, T.; Reichenbacher, J.; Reitzner, S. D.; Renshaw, A.; Rescia, S.; Resnati, F.; Reynolds, A.; Riccobene, G.; Rice, L. C. J.; Rielage, K.; Rigaut, Y.; Rivera, D.; Rochester, Lynn; Roda, M.; Rodrigues, P. A.; Alonso, M. J. 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doi:10.1140/epjc/s10052-021-09007-w

Cited by 101 publications

(98 citation statements)

References 296 publications

(393 reference statements)

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“…Interestingly, even though our implementation of normalization uncertainties is very different than in ref. [104] we recover a similar result here, shown by the solid blue line in the lower panel of figure 5. This already indicates that normalization uncertainties are not playing a relevant role in the fit, which is expected since the effect from a sterile neutrino would be detected by looking at spectral distortions in the event rates.…”

Section: Jhep08(2021)065supporting

confidence: 90%

“…In fact, the combination of data from different channels for a sterile neutrino search was already performed for the DUNE experiment in ref. [104], leading to an impressive sensitivity to sterile neutrinos which reached values of the effective mixing angle of sin 2 2θ µe 10 −6 in the region where ∆m 2 41 ∼ O(1 − 10) eV 2 . However, in ref.…”

Section: Jhep08(2021)065mentioning

confidence: 99%

“…However, in ref. [104] only normalization uncertainties were included in the analysis. Interestingly, even though our implementation of normalization uncertainties is very different than in ref.…”

Section: Jhep08(2021)065mentioning

confidence: 99%

See 2 more Smart Citations

New physics from oscillations at the DUNE near detector, and the role of systematic uncertainties

Coloma

López‐Pavón

Rosauro-Alcaraz

et al. 2021

J. High Energ. Phys.

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We study the capabilities of the DUNE near detector to probe deviations from unitarity of the leptonic mixing matrix, the 3+1 sterile formalism and Non-Standard Interactions affecting neutrino production and detection. We clarify the relation and possible mappings among the three formalisms at short-baseline experiments, and we add to current analyses in the literature the study of the νμ→ ντ appearance channel. We study in detail the impact of spectral uncertainties on the sensitivity to new physics using the DUNE near detector, which has been widely overlooked in the literature. Our analysis shows that this plays an important role on the results and, in particular, that it can lead to a strong reduction in the sensitivity to sterile neutrinos from νμ→ νe transitions, by more than two orders of magnitude. This stresses the importance of a joint experimental and theoretical effort to improve our understanding of neutrino nucleus cross sections, as well as hadron production uncertainties and beam focusing effects. Nevertheless, even with our conservative and more realistic implementation of systematic uncertainties, we find that an improvement over current bounds in the new physics frameworks considered is generally expected if spectral uncertainties are below the 5% level.

show abstract

Section: Jhep08(2021)065supporting

confidence: 90%

Section: Jhep08(2021)065mentioning

confidence: 99%

See 1 more Smart Citation

New physics from oscillations at the DUNE near detector, and the role of systematic uncertainties

Coloma

López‐Pavón

Rosauro-Alcaraz

et al. 2021

J. High Energ. Phys.

View full text Add to dashboard Cite

show abstract

“…The oscillation physics program is centered on a measurement of any violation in neutrino oscillations, potentially connected to the matter-antimatter asymmetry observed in our universe, and will also yield precise measurements of mixing angles and the neutrino mass ordering while providing a strict test of the three-neutrino oscillation model with both appearance and disappearance measurements in neutrino and antineutrino beams [1]. These measurements are part of a broader physics program including sensitivity to neutrino astrophysics signals such as supernovae [2] and solar neutrinos [3], nucleon decay, and a wide array of searches for Beyond the Standard Model (BSM) physics [4].…”

Section: Introductionmentioning

confidence: 99%

The DUNE Near Detector

Mastbaum¹

2022

Proceedings of the European Physical Society Conference on High Energy Physics — PoS(EPS-HEP2021)

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The Deep Underground Neutrino Experiment (DUNE) is an upcoming long-baseline neutrino experiment which will study neutrino oscillations. Neutrino oscillations will be detected at the DUNE Far Detector 1300 km away from the start of the beam at Fermilab. The DUNE Near Detector (ND) will be located on-site at Fermilab, and will be used to provide an initial characterization of the neutrino beam, as well as to constrain systematic uncertainties on neutrino oscillation measurements. The detector suite consists of a modular LArTPC (ND-LAr), a magnetized gaseous argon time projection chamber (ND-GAr) surrounded by an electromagnetic calorimeter, and the System for on-Axis Neutrino Detection (SAND), composed of a magnetized electromagnetic calorimeter and inner tracker. In these proceedings, these detectors and their physics goals will be discussed.

show abstract

“…The next-generation long-baseline experiment DUNE [62,63], with its high-intensity neutrino beam, huge statistics, wide-band spectrum and improved systematic uncertainties, is in an excellent position to probe matter NSI [44,45,50,53] and BSM physics involving neutrinos in general [64]. At present, the full physics potential of liquid argon time projection chamber (LArTPC) detectors is still being explored.…”

Section: Introductionmentioning

confidence: 99%

Impact of improved energy resolution on DUNE sensitivity to neutrino non-standard interactions

Chatterjee

Dev²,

Machado

2021

J. High Energ. Phys.

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The full physics potential of the next-generation Deep Underground Neutrino Experiment (DUNE) is still being explored. In particular, there have been some recent studies on the possibility of improving DUNE’s neutrino energy reconstruction. The main motivation is that a better determination of the neutrino energy in an event-by-event basis will translate into an improved measurement of the Dirac C P phase and other neutrino oscillation parameters. To further motivate studies and improvements on the neutrino energy reconstruction, we evaluate the impact of energy resolution at DUNE on an illustrative new physics scenario, viz. non-standard interactions (NSI) of neutrinos with matter. We show that a better energy resolution in comparison to the ones given in the DUNE conceptual and technical design reports may significantly enhance the experimental sensitivity to NSI, particularly when degeneracies are present. While a better reconstruction of the first oscillation peak helps disentangling standard C P effects from those coming from NSIs, we find that the second oscillation peak also plays a nontrivial role in improving DUNE’s sensitivity.

show abstract

Prospects for beyond the Standard Model physics searches at the Deep Underground Neutrino Experiment

Cited by 101 publications

References 296 publications

New physics from oscillations at the DUNE near detector, and the role of systematic uncertainties

New physics from oscillations at the DUNE near detector, and the role of systematic uncertainties

The DUNE Near Detector

Impact of improved energy resolution on DUNE sensitivity to neutrino non-standard interactions

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