CV Lattes
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Universidade Estadual de Campinas (UNICAMP). Instituto de Física Gleb Wataghin (IFGW) (Institutional affiliation for the last research proposal) Birthplace: Brazil
Graduate in Physics from Federal University of Rio Grande do Sul (1990) and PhD in Physics from State University UNESP(1995). Has experience in Elementary Particles Physics, acting on the neutrino physics. I am research fellow type II of CNPQ and coordinator of the Thematic project on Challenges in XXVI Century in Neutrino physics. In 2021, it was choosen as Dean of Graduate Commission. It is referee of Phyisical Review Letters, Physical Review D, Journal of Cosmology and Physics, Reports on Progress on Physics, Journal of High Energy Physics, European Physical Journal C, New Journal of Physics. It was Dean of the Cosmic Rays and Chronology Department from 2008-2012. I was Fulbright fellow in 2011/2012. Since 2013 I am member of American Physical Society and since 1993 I am member of Brazilian Physical Society. I am member of Particle and Fields committee from Brazilian Physics Society. I was chairman of the Departament seminars from 2002 to 2012. (Source: Lattes Curriculum)
This is a proposal for exchange activities between UNICAMP, UFABC and Duke University to work on studies of supernova neutrino sensitivity of the Deep Underground Neutrino Experiment (DUNE). We will produce publications evaluating the sensitivity of DUNE to neutrino absolute mass, to the neutrino mass hierarchy, and to non-standard neutrino interactions from observation of the burst of ne…
In the last two decades Neutrino Physics had a extraordinary growth. The experimental discovery of the neutrino oscillations with the determination of the mixing angles and the mass differences, the long awaited solution for the old anomalies of solar and atmospheric neutrinos and the central role that neutrinos have in the cosmological evolution of the Universe are examples that foster t…
The neutrinos oscillate! It was probed in many different experiments that neutrinos oscillate. One exciting research area is to understand some basic neutrino properties that we did not the answer yet. One is the possibility of neutrinos violate the CP symmetry and another one is to understand the pattern of neutrino masses by the determination of the neutrino hierarchies. Both topics c…
The neutrinos oscillate! It was probed in many different experiments that neutrinos oscillate. One exciting research area is to understand some basic neutrino properties that we did not the answer yet. One question is if the neutrino is a unstable particle. We will test a scenario where the parent neutrino can decay into active neutrinos and a massless boson. These scenarios were tested f…
(Only some records are available in English at this moment)
The state of the art in neutrino physics we know that neutrinos oscillated and mix with each other. This is the first signal of lepton violation. We will study scenarios of the presence of new interactions of neutrinos and the impact of such interactions in the near future of long-baseline experiments. (AU)
The present paradigm of neutrino oscillation is that is due to neutrinos have mass and they mix between them. This is one of first signals of lepton number violation, but still no other source of violation of lepton number is known. We want to study the formalism of beyond the standard model interactions in the new generation of high precision long-baseline experiments (AU)
The neutrinos oscillate! It was probed in many different experiments that neutrinos oscillate. One exciting research area is to understand some basic neutrino properties that we did not the answer yet. One is the possibility of neutrinos violate the CP symmetry and another one is to understand the pattern of neutrino masses by the determination of the neutrino hierarchies. . Both topi…
Over the past decades, the Standard Model (SM) of particle physics has been an extremely successful theory, providing an excellent description of most of the phenomena of particle physics. Yet, there are fundamental physics phenomena that the SM does not explain adequately: for instance, the origin of neutrino masses, Dark Matter, matter-antimatter asymmetry in the universe. To solve thes…
The most ambitious neutrino program today is hosted by Fermi National Accelerator Laboratory - Fermilab (IL-USA). The goal is to have a series of experiments that will extensively cover the still-open problems in neutrino physics such as mass hierarchy, CP violation, precise measurements of all mixing parameters and the three family paradigm. The entire program is based on the Liquid Argo…
In the latest 30 years the research of neutrino physics culminate with the Nobel Prize in 2015 for discovery of neutrino oscillation give us, a signal for New Physics is necessary to understand the different transitions between neutrino flavours. The more economical scenario is the existence of three neutrinos with non-zero mass differences and mixing angles. This scenario can be challeng…
(Only some records are available in English at this moment)
Supernovae produced by the collapse of massive stars produce large fluxes of neutrinos that could be detected on the Earth. However, many details of the neutrino flavor transformations at this stage of stellar evolution are not yet fully understood, and new phenomena, such as collective oscillations, could arise. The produced neutrino wave-packets are very short and, therefore, might unde…
It was probed in many different experiments that neutrinos oscillate. With this knowledge we intend to study other neutrino properties that are still open questions. One interesting case is testing neutrino mass hierarchy and CP symmetry violation in long-baseline experiments, which were designed to maximize the study of these two open questions. We also want to study in this project othe…
The dynamics of flavor physicsconstitutes one of the main unknown in particle physics: whatprinciple should predict the pattern of masses and mixing angles, aswell as flavor replication. These issues lie beyond the Standard Model(SM). An important physical concept that is closely related to flavorphysics are mass generating mechanisms. Special ones are necessary tounderstand why neutrinos…
(Only some records are available in English at this moment)
| 2 / 2 | Ongoing research grants |
| 18 / 15 | Completed research grants |
| 3 / 3 | Ongoing scholarships in Brazil |
| 17 / 10 | Completed scholarships in Brazil |
| 5 / 4 | Completed scholarships abroad |
| 45 / 34 | All research grants and scholarships |
| Associated processes | |
(References retrieved automatically from Web of Science and SciELO through information on FAPESP grants and their corresponding numbers as mentioned in the publications by the authors)
| Publications | 67 |
| Citations | 552 |
| Cit./Article | 8.2 |
| Data from Web of Science | |
BHARTI, SUMAN; PRAKASH, SUPRABH; RAHAMAN, USHAK; SANKAR, S. UMA. Understanding the degeneracies in NOvA data. Journal of High Energy Physics, n. 9, SEP 7 2018. Web of Science Citations: 0. (14/19164-6, 17/02361-1)
NISHI, C. C.; SANCHEZ-VEGA, B. L.; SOUZA SILVA, G.. Mu-tau reflection symmetry with a high scale texture-zero. Journal of High Energy Physics, n. 9, SEP 7 2018. Web of Science Citations: 5. (14/19164-6, 18/07903-0)
CHATTERJEE, SABYA SACHI; PASQUINI, PEDRO; VANE, J. W. F.. Probing atmospheric mixing and leptonic CP violation in current and future long baseline oscillation experiments. Physics Letters B, v. 771, p. 524-531, AUG 10 2017. Web of Science Citations: 12. (14/19164-6, 14/05133-1, 15/16809-9)
PASQUINI, P. S.; PERES, O. L. G.. Bounds on neutrino-scalar Yukawa coupling. Physical Review D, v. 93, n. 5, MAR 9 2016. Web of Science Citations: 19. (12/16389-1, 14/05133-1, 15/16809-9)
MONTERO, J. C.; ROMERO CASTELLANOS, ANA R.; SANCHEZ-VEGA, B. L.. Axion dark matter in a 3-3-1 model. Physical Review D, v. 97, n. 6, MAR 30 2018. Web of Science Citations: 4. (14/19164-6)
BARRETO, E. R.; DIAS, A. G.; LEITE, J.; NISHI, C. C.; OLIVEIRA, R. L. N.; VIEIRA, W. C.. Hierarchical fermions and detectable Z ` from effective two-Higgs-triplet 3-3-1 model. Physical Review D, v. 97, n. 5, MAR 29 2018. Web of Science Citations: 4. (13/22079-8, 14/19164-6)
GE, SHAO-FENG; PASQUINI, PEDRO; TORTOLA, M.; VALLE, J. W. F.. Measuring the leptonic CP phase in neutrino oscillations with nonunitary mixing. Physical Review D, v. 95, n. 3, FEB 16 2017. Web of Science Citations: 19. (14/19164-6, 14/05133-1, 15/16809-9)
TABRIZI, ZAHRA; PERES, O. L. G.. Hidden interactions of sterile neutrinos as a probe for new physics. Physical Review D, v. 93, n. 5, MAR 3 2016. Web of Science Citations: 2. (12/16389-1)
GOMES, R. A.; GOMES, A. L. G.; PERES, O. L. G.. Constraints on neutrino decay lifetime using long-baseline charged and neutral current data. Physics Letters B, v. 740, p. 345-352, JAN 5 2015. Web of Science Citations: 23. (12/16389-1)
ESMAILI, A.; GRATIERI, D. R.; GUZZO, M. M.; DE HOLANDA, P. C.; PERES, O. L. G.; VALDIVIESSO, G. A.. Constraining the violation of the equivalence principle with IceCube atmospheric neutrino data. Physical Review D, v. 89, n. 11, JUN 11 2014. Web of Science Citations: 9. (12/16389-1, 09/17924-5)
ESMAILI, ARMAN; KEMP, ERNESTO; PERES, O. L. G.; TABRIZI, ZAHRA. Probing light sterile neutrinos in medium baseline reactor experiments. Physical Review D, v. 88, n. 7, OCT 25 2013. Web of Science Citations: 12. (12/16389-1, 10/07359-6, 09/17924-5)
VIEYRO, F. L.; ROMERO, G. E.; PERES, O. L. G.. Neutrinos from collapsars. Astronomy & Astrophysics, v. 558, OCT 2013. Web of Science Citations: 3. (12/16389-1)
ESMAILI, ARMAN; SMIRNOV, ALEXEI YU.. Restricting the LSND and MiniBooNE sterile neutrinos with the IceCube atmospheric neutrino data. Journal of High Energy Physics, n. 12, DEC 2 2013. Web of Science Citations: 19. (09/17924-5)
PICORETI, R.; GUZZO, M. M.; DE HOLANDA, P. C.; PERES, O. L. G.. Neutrino decay and solar neutrino seasonal effect. Physics Letters B, v. 761, p. 70-73, OCT 10 2016. Web of Science Citations: 13. (12/16389-1)
STENICO, G. V.; FORERO, D. V.; PERES, O. L. G.. A short travel for neutrinos in Large Extra Dimensions. Journal of High Energy Physics, n. 11, NOV 23 2018. Web of Science Citations: 0. (17/12904-2, 16/00272-9, 17/01749-6, 16/08308-2, 14/19164-6)
BARELA, MARIO W.; PLEITEZ, V. Trimuon production at the LHC. Physical Review D, v. 101, n. 1, JAN 28 2020. Web of Science Citations: 0. (14/19164-6)
IVANOV, IGOR P.; NISHI, CELSO C.. Discriminating between CP and family transformations in the bilinear space of the N-Higgs-doublet model. Physical Review D, v. 101, n. 1, JAN 28 2020. Web of Science Citations: 0. (14/19164-6)
CHAVES, M. E.; GRATIERI, D. R.; PERES, O. L. G.. Improvements on perturbative oscillation formulas including non-standard neutrino interactions. JOURNAL OF PHYSICS G-NUCLEAR AND PARTICLE PHYSICS, v. 48, n. 1, JAN 2021. Web of Science Citations: 0. (14/19164-6)
PORTO-SILVA, YAGO P.; PRAKASH, SUPRABH; PERES, O. L. G.; NUNOKAWA, HIROSHI; MINAKATA, HISAKAZU. Constraining visible neutrino decay at KamLAND and JUNO. EUROPEAN PHYSICAL JOURNAL C, v. 80, n. 10, OCT 29 2020. Web of Science Citations: 0. (16/08308-2, 19/22961-9, 14/19164-6, 17/02361-1, 17/05515-0)
DE GOUVEA, ANDRE; MACHADO, PEDRO A. N.; PEREZ-GONZALEZ, YUBER F.; TABRIZI, ZAHRA. Measuring the Weak Mixing Angle in the DUNE near-Detector Complex. Physical Review Letters, v. 125, n. 5, JUL 29 2020. Web of Science Citations: 0. (18/21745-8)
FALKOWSKI, ADAM; GONZALEZ-ALONSO, MARTIN; TABRIZI, ZAHRA. Consistent QFT description of non-standard neutrino interactions. Journal of High Energy Physics, n. 11, NOV 11 2020. Web of Science Citations: 0. (18/21745-8)
CHERCHIGLIA, A. L.; NISHI, C. C.. Solving the strong CP problem with non-conventional CP. Journal of High Energy Physics, n. 3, MAR 7 2019. Web of Science Citations: 1. (14/19164-6)
MACHADO, A. C. B.; MONTANO, J.; PLEITEZ, V. Lepton flavor violating processes in the minimal 3-3-1 model with sterile neutrinos. JOURNAL OF PHYSICS G-NUCLEAR AND PARTICLE PHYSICS, v. 46, n. 11, NOV 2019. Web of Science Citations: 1. (13/09173-5, 14/19164-6)
IVANOV, IGOR P.; NISHI, CELSO C.; TRAUTNER, ANDREAS. Beyond basis invariants. EUROPEAN PHYSICAL JOURNAL C, v. 79, n. 4, APR 8 2019. Web of Science Citations: 2. (14/19164-6)
ROMERO CASTELLANOS, ANA R.; ALVAREZ-SALAZAR, C. E.; SANCHEZ-VEGA, B. L.. Constraints on axionic dark matter in the 3-3-1 model. ASTRONOMISCHE NACHRICHTEN, v. 340, n. 1-3, SI, p. 131-134, JAN-MAR 2019. Web of Science Citations: 0. (14/19164-6)
GRATIERI, D. R.; GUZZO, M. M.; PERES, O. L. G.. Impact of standard neutrino oscillations and systematics on proton lifetime measurements. JOURNAL OF PHYSICS G-NUCLEAR AND PARTICLE PHYSICS, v. 46, n. 7, JUL 2019. Web of Science Citations: 0. (14/19164-6)
GAGO, ALBERTO M.; GOMES, RICARDO A.; GOMES, ABNER L. G.; JONES-PEREZ, JOEL; PERES, ORLANDO L. G.. Visible neutrino decay in the light of appearance and disappearance long-baseline experiments. Journal of High Energy Physics, n. 11, NOV 7 2017. Web of Science Citations: 12. (14/19164-6)
FORTES, E. C. F. S.; PLEITEZ, V.; STECKER, F. W.. Secluded and putative flipped dark matter and Stueckelberg extensions of the standard model. Journal of Cosmology and Astroparticle Physics, n. 2, FEB 2018. Web of Science Citations: 1. (14/19164-6)
PASQUINI, PEDRO; CHULIA, SALVADOR CENTELLES; VALLE, J. W. F.. Neutrino oscillations from warped flavor symmetry: Predictions for long baseline experiments T2K, NOvA, and DUNE. Physical Review D, v. 95, n. 9, MAY 31 2017. Web of Science Citations: 9. (14/19164-6, 14/05133-1, 15/16809-9)
DE CONTO, G.; PLEITEZ, V.. Hadronic resonances with exotic electric charge. Physical Review D, v. 96, n. 7, OCT 20 2017. Web of Science Citations: 0. (14/19164-6)
PASQUINI, PEDRO. Reactor and atmospheric neutrino mixing angles' correlation as a probe for new physics. Physical Review D, v. 96, n. 9, NOV 20 2017. Web of Science Citations: 2. (14/19164-6, 14/05133-1, 15/16809-9)
CHERCHIGLIA, A. L.; NISHI, C. C.. One-loop considerations for coexisting vacua in the CP conserving 2HDM. Journal of High Energy Physics, n. 11, NOV 17 2017. Web of Science Citations: 1. (13/22079-8, 14/19164-6)
GUZZO, M. M.; DE HOLANDA, P. C.; PERES, O. L. G.. New limits on neutrino magnetic moment through nonvanishing 13-mixing. Physical Review D, v. 97, n. 9, MAY 18 2018. Web of Science Citations: 2. (12/16389-1, 14/19164-6)
IVANOV, IGOR P.; NISHI, CELSO C.; SILVA, JOAO P.; TRAUTNER, ANDREAS. Basis-invariant conditions for CP symmetry of order four. Physical Review D, v. 99, n. 1, JAN 30 2019. Web of Science Citations: 5. (14/19164-6)
KING, STEPHEN F.; NISHI, CELSO C.. Mu-tau symmetry and the Littlest Seesaw. Physics Letters B, v. 785, p. 391-398, OCT 10 2018. Web of Science Citations: 9. (14/19164-6)
DE SOUZA, GIBRAN H.; KEMP, ERNESTO. The influence of magnetic field geometry in neutron stars' crustal oscillations. ASTRONOMISCHE NACHRICHTEN, v. 340, n. 9-10, SI, p. 904-908, NOV-DEC 2019. Web of Science Citations: 0. (14/19164-6)
FORTES, E. C. F. S.; MACHADO, A. C. B.; MONTANO, J.; PLEITEZ, V. Lepton masses and mixing in a scotogenic model. Physics Letters B, v. 803, APR 10 2020. Web of Science Citations: 0. (14/19164-6, 18/21532-4)
COLOMA, PILAR; FORERO, DAVID V.; PARKE, STEPHEN J.. DUNE sensitivities to the mixing between sterile and tau neutrinos. Journal of High Energy Physics, n. 7, JUL 11 2018. Web of Science Citations: 5. (14/19164-6, 17/01749-6)
NIZAM, MOHAMMAD; BHARTI, SUMAN; PRAKASH, SUPRABH; RAHAMAN, USHAK; SANKAR, S. UMA. Tensions between the appearance data of T2K and NO nu A. MODERN PHYSICS LETTERS A, v. 35, n. 6, FEB 28 2020. Web of Science Citations: 0. (14/19164-6, 17/02361-1)
NISHI, CELSO C.; FONG, CHEE SHENG. Leptogenesis in the mu tau basis. Journal of High Energy Physics, n. 7, JUL 21 2020. Web of Science Citations: 0. (19/11197-6, 14/19164-6)
DE GOUVEA, ANDRE; PERES, O. L. G.; PRAKASH, SUPRABH; STENICO, V, G.. On the decaying-sterile-neutrino solution to the electron (anti)neutrino appearance anomalies. Journal of High Energy Physics, n. 7, JUL 21 2020. Web of Science Citations: 0. (16/00272-9, 17/02361-1, 17/12904-2, 14/19164-6)
ALVAREZ-SALAZAR, C. E.; PERES, O. L. G.; SANCHEZ-VEGA, B. L.. The dark matter puzzle in a class of models with gauge symmetry SU(3)(C) circle times SU(3)(L) circle times U(1)(N). ASTRONOMISCHE NACHRICHTEN, v. 340, n. 1-3, SI, p. 135-138, JAN-MAR 2019. Web of Science Citations: 0. (14/19164-6)
BALIEIRO GOMES, G.; FORERO, D. V.; GUZZO, M. M.; DE HOLANDA, P. C.; OLIVEIRA, R. L. N.. Quantum decoherence effects in neutrino oscillations at DUNE. Physical Review D, v. 100, n. 5, SEP 17 2019. Web of Science Citations: 0. (17/01749-6, 14/19164-6, 18/19365-2)
ANA R. ROMERO CASTELLANOS; C. E. ALVAREZ-SALAZAR; P. C. DE HOLANDA. Testing discrepancies in the measurement of the acceleration of gravity in a physical pendulum experiment. Revista Brasileira de Ensino de Física, v. 42, p. -, 2020. (14/19164-6)
DIAS, A. G.; LEITE, J.; LOPES, D. D.; NISHI, C. C.. Fermion mass hierarchy and double seesaw mechanism in a 3-3-1 model with an axion. Physical Review D, v. 98, n. 11, DEC 10 2018. Web of Science Citations: 5. (17/23027-2, 14/19164-6)
SANCHEZ-VEGA, B. L.; GAMBINI, GUILLERMO; ALVAREZ-SALAZAR, C. E.. Vacuum stability conditions of the economical 3-3-1 model from copositivity. EUROPEAN PHYSICAL JOURNAL C, v. 79, n. 4, APR 3 2019. Web of Science Citations: 2. (14/19164-6)
DE SALAS, P. F.; FORERO, D. V.; TERNES, C. A.; TORTOLA, M.; VALLE, J. W. F.. Status of neutrino oscillations 2018: 3 sigma hint for normal mass ordering and improved CP sensitivity. Physics Letters B, v. 782, p. 633-640, JUL 10 2018. Web of Science Citations: 171. (17/01749-6, 14/19164-6)
PASQUINI, PEDRO. Long-Baseline Oscillation Experiments as a Tool to Probe High Energy Flavor Symmetry Models. Advances in High Energy Physics, 2018. Web of Science Citations: 1. (14/19164-6, 14/05133-1, 15/16809-9)
HAGEDORN, C.; MOHAPATRA, R. N.; MOLINARO, E.; NISHI, C. C.; PETCOV, S. T.. CP violation in the lepton sector and implications for leptogenesis. International Journal of Modern Physics A, v. 33, n. 5-6, SI, FEB 28 2018. Web of Science Citations: 15. (13/22079-8, 14/19164-6)
CHATTERJEE, SABYA SACHI; MASUD, MEHEDI; PASQUINI, PEDRO; VALLE, J. W. F.. Cornering the revamped BMV model with neutrino oscillation data. Physics Letters B, v. 774, p. 179-182, NOV 10 2017. Web of Science Citations: 11. (15/16809-9, 14/05133-1, 14/19164-6)
PASQUINI, PEDRO. Long-Baseline Oscillation Experiments as a Tool to Probe High Energy Flavor Symmetry Models. Advances in High Energy Physics, 2018. Web of Science Citations: 1. (14/19164-6, 14/05133-1, 15/16809-9)
HAGEDORN, C.; MOHAPATRA, R. N.; MOLINARO, E.; NISHI, C. C.; PETCOV, S. T.. CP violation in the lepton sector and implications for leptogenesis. International Journal of Modern Physics A, v. 33, n. 5-6, SI, FEB 28 2018. Web of Science Citations: 15. (13/22079-8, 14/19164-6)
ALVAREZ-SALAZAR, C. E.; PERES, O. L. G.; SANCHEZ-VEGA, B. L.. The dark matter puzzle in a class of models with gauge symmetry SU(3)(C) circle times SU(3)(L) circle times U(1)(N). ASTRONOMISCHE NACHRICHTEN, v. 340, n. 1-3, SI, p. 135-138, JAN-MAR 2019. Web of Science Citations: 0. (14/19164-6)
BALIEIRO GOMES, G.; FORERO, D. V.; GUZZO, M. M.; DE HOLANDA, P. C.; OLIVEIRA, R. L. N.. Quantum decoherence effects in neutrino oscillations at DUNE. Physical Review D, v. 100, n. 5, SEP 17 2019. Web of Science Citations: 0. (17/01749-6, 14/19164-6, 18/19365-2)
DIAS, A. G.; LEITE, J.; LOPES, D. D.; NISHI, C. C.. Fermion mass hierarchy and double seesaw mechanism in a 3-3-1 model with an axion. Physical Review D, v. 98, n. 11, DEC 10 2018. Web of Science Citations: 5. (17/23027-2, 14/19164-6)
SANCHEZ-VEGA, B. L.; GAMBINI, GUILLERMO; ALVAREZ-SALAZAR, C. E.. Vacuum stability conditions of the economical 3-3-1 model from copositivity. EUROPEAN PHYSICAL JOURNAL C, v. 79, n. 4, APR 3 2019. Web of Science Citations: 2. (14/19164-6)
CHATTERJEE, SABYA SACHI; MASUD, MEHEDI; PASQUINI, PEDRO; VALLE, J. W. F.. Cornering the revamped BMV model with neutrino oscillation data. Physics Letters B, v. 774, p. 179-182, NOV 10 2017. Web of Science Citations: 11. (14/19164-6, 14/05133-1, 15/16809-9)
GANDHI, RAJ; KAYSER, BORIS; PRAKASH, SUPRABH; ROY, SAMIRAN. What measurements of neutrino neutral current events can reveal. Journal of High Energy Physics, n. 11, NOV 29 2017. Web of Science Citations: 2. (17/02361-1, 14/19164-6)
DE HOLANDA, P. C.. Solar neutrino limits on decoherence. Journal of Cosmology and Astroparticle Physics, n. 3, MAR 2020. Web of Science Citations: 0. (19/15600-0, 14/19164-6)
ALVAREZ-SALAZAR, C. E.; PERES, O. L. G.. Constraining the 3-3-1 model with heavy neutral leptons using (g 2)(mu) and dark matter observables. Physical Review D, v. 103, n. 3, FEB 25 2021. Web of Science Citations: 0. (14/19164-6)
MIRANDA, O. G.; PASQUINI, PEDRO; TORTOLA, M.; VALLE, J. W. F.. Exploring the potential of short-baseline physics at Fermilab. Physical Review D, v. 97, n. 9, MAY 21 2018. Web of Science Citations: 2. (14/19164-6, 14/05133-1, 15/16809-9)
FONG, CHEE SHENG; MINAKATA, HISAKAZU; NUNOKAWA, HIROSHI. Non-unitary evolution of neutrinos in matter and the leptonic unitarity test. Journal of High Energy Physics, n. 2, FEB 4 2019. Web of Science Citations: 1. (12/10995-7, 16/01343-7, 14/19164-6)
DE GOUVEA, ANDRE; KELLY, KEVIN J.; STENICO, V, G.; PASQUINI, PEDRO. Physics with beam tau-neutrino appearance at DUNE. Physical Review D, v. 100, n. 1, JUL 10 2019. Web of Science Citations: 2. (17/12904-2, 14/05133-1, 14/19164-6, 16/00272-9, 15/16809-9)
CARNEIRO, S.; DE HOLANDA, P. C.; PIGOZZO, C.; SOBREIRA, F.. Is the H-0 tension suggesting a fourth neutrino generation?. Physical Review D, v. 100, n. 2, JUL 9 2019. Web of Science Citations: 6. (14/19164-6)
DE SOUZA, GIBRAN H.; KEMP, ERNESTO. The influence of magnetic field geometry in neutron stars' crustal oscillations. ASTRONOMISCHE NACHRICHTEN, DEC 2019. Web of Science Citations: 0. (14/19164-6)
CHERCHIGLIA, A. L.; NISHI, C. C.. Consequences of vector-like quarks of Nelson-Barr type. Journal of High Energy Physics, n. 8, AUG 24 2020. Web of Science Citations: 0. (14/19164-6)
DIAZ, HENRY; PLEITEZ, V; PEREYRA RAVINEZ, O.. Dirac neutrinos in an SU(2) left-right symmetric model. Physical Review D, v. 102, n. 7, OCT 8 2020. Web of Science Citations: 0. (14/19164-6)
DE GOUVEA, ANDRE; PERES, O. L. G.; PRAKASH, SUPRABH; STENICO, V, G.. On the decaying-sterile-neutrino solution to the electron (anti)neutrino appearance anomalies. Journal of High Energy Physics, n. 7, JUL 21 2020. Web of Science Citations: 0. (16/00272-9, 17/02361-1, 17/12904-2, 14/19164-6)
(References retrieved automatically from State of São Paulo Research Institutions)
PASQUINI, Pedro Simoni. Fenomenologia em modelos com dimensões extras. Dissertação (Mestrado) - Instituto de Física Gleb Wataghin. Universidade Estadual de Campinas (UNICAMP). (11/15823-7)
GRATIERI, Diego Rossi. Fenomenologia de neutrinos atmosféricos. Dissertação (Mestrado) - Instituto de Fisica Gleb Wataghin. Universidade Estadual de Campinas (UNICAMP). (04/04579-4)
STENICO, Gabriela Vitti. Cálculo da produção de neutrinos atmosféricos. Dissertação (Mestrado) - Instituto de Física Gleb Wataghin. Universidade Estadual de Campinas (UNICAMP). (14/00347-3)
SALGADO, Maurílio Ferreira. Fenomenologia de medidas diretas de massa de neutrino. Dissertação (Mestrado) - Instituto de Física Gleb Wataghin. Universidade Estadual de Campinas (UNICAMP). (07/06012-0)
LESSA, André Paniago. Supersimetria em fisica de particulas. Dissertação (Mestrado) - Instituto de Física Gleb Wataghin. Universidade Estadual de Campinas (UNICAMP). (04/10686-8)
PERES, Orlando Luis Goulart. Fenomenologia de neutrinos massivos. 87 f. Tese (Doutorado) - Instituto de Física Teórica. Universidade Estadual Paulista. São Paulo. (93/01958-8)