Showing total 86 results

1. Robustness of ARS leptogenesis in scalar extensions.

Author

Fischer, Oliver, Lindner, Manfred, and van der Woude, Susan

Subjects

STERILE neutrinos, NEUTRINOS, STANDARD model (Nuclear physics), NEUTRINO oscillation, BOSONS

Abstract

Extensions of the Standard Model (SM) with sterile neutrinos are well motivated from the observed oscillations of the light neutrinos and they have shown to successfully explain the Baryon Asymmetry of the Universe (BAU) through, for instance, the so-called ARS leptogenesis. Sterile neutrinos can be added in minimal ways to the SM, but many theories exist where sterile neutrinos are not the only new fields. Such theories often include scalar bosons, which brings about the possibility of further interactions between the sterile neutrinos and the SM. In this paper we consider an extension of the SM with two sterile neutrinos and one scalar singlet particle and investigate the effect that an additional, thermalised, scalar has on the ARS leptogenesis mechanism. We show that in general the created asymmetry is reduced due to additional sterile neutrino production from scalar decays. When sterile neutrinos and scalars are discovered in the laboratory, our results will provide information on the applicability of the ARS leptogenesis mechanism. [ABSTRACT FROM AUTHOR]

Published

2022

2. Neutral exotica at FASERν and SND@LHC.

Author

Ansarifard, S. and Farzan, Y.

Subjects

STANDARD model (Nuclear physics), HIGGS bosons, STATISTICAL sampling, NEUTRINOS, QUARKS

Abstract

The (g − 2)μ anomaly indicates that the second generation of leptons should have new interactions beyond the standard model. The high flux of νμ and ν ¯ μ at the forward experiments such as FASERν and SND@LHC makes them suitable setups to search for new interactions of the second generation leptons. In this paper, we build a model in which the second generation left-handed leptons couple to a new right-handed neutrino, N and a new Higgs doublet which also couples to the quarks. The scattering of high energy νμ off nuclei can produce N. We investigate how forward experiments can test this model by looking for the N production vertex followed by the displaced vertex of the N decay. Discovering even a single such event can be a harbinger to look for the spectacular signals of the new Higgs doublet production at the LHC. We discuss the possibility of explaining the (g − 2)μ anomaly by adding more generations of N which will lead to chain decays of N and multiple leptons with distinct signals both at forward experiments and at the CMS and ATLAS detectors. Finally, we show that by adding a new light singlet scalar mixed with the neutral component of the new Higgs doublet (i.e., 2HDM+S model), the statistics of the data sample can be dramatically increased. [ABSTRACT FROM AUTHOR]

Published

2022

3. On the short-range behavior of neutrino forces beyond the Standard Model: from 1/r5 to 1/r4, 1/r2, and 1/r.

Author

Xu, Xun-Jie and Yu, Bingrong

Subjects

STANDARD model (Nuclear physics), MOMENTUM transfer, NEUTRINOS, PSEUDOPOTENTIAL method

Abstract

The exchange of a pair of neutrinos between two objects, separated by a distance r, leads to a long-range effective potential proportional to 1/r5, assuming massless neutrinos and four-fermion contact interactions. In this paper, we investigate how this known form of neutrino-mediated potentials might be altered if the distance r is sufficiently short, corresponding to a sufficiently large momentum transfer which could invalidate the contact interactions. We consider two possible scenarios to open up the contact interactions by introducing a t-channel or an s-channel mediator. We derive a general formula that is valid to describe the potential in all regimes as long as the external particles remain non-relativistic. In both scenarios, the potential decreases as 1/r5 in the long-range limit as expected. In the short-range limit, the t-channel potential exhibits the Coulomb-like behavior (i.e. proportional to 1/r), while the s-channel potential exhibits 1/r4 and 1/r2 behaviors. [ABSTRACT FROM AUTHOR]

Published

2022

4. Long-lived heavy neutral leptons at the LHC: four-fermion single-NR operators.

Author

Beltrán, Rebeca, Cottin, Giovanna, Helo, Juan Carlos, Hirsch, Martin, Titov, Arsenii, and Wang, Zeren Simon

Subjects

STANDARD model (Nuclear physics), OPERATOR theory, NEUTRINOS, FERMIONS, PHYSICS

Abstract

Interest in searches for heavy neutral leptons (HNLs) at the LHC has increased considerably in the past few years. In the minimal scenario, HNLs are produced and decay via their mixing with active neutrinos in the Standard Model (SM) spectrum. However, many SM extensions with HNLs have been discussed in the literature, which sometimes change expectations for LHC sensitivities drastically. In the NRSMEFT, one extends the SM effective field theory with operators including SM singlet fermions, which allows to study HNL phenomenology in a "model independent" way. In this paper, we study the sensitivity of ATLAS to HNLs in the NRSMEFT for four-fermion operators with a single HNL. These operators might dominate both production and decay of HNLs, and we find that new physics scales in excess of 20 TeV could be probed at the high-luminosity LHC. [ABSTRACT FROM AUTHOR]

Published

2022

5. Searching for physics beyond the Standard Model in an off-axis DUNE near detector.

Author

Breitbach, Moritz, Buonocore, Luca, Frugiuele, Claudia, Kopp, Joachim, and Mittnacht, Lukas

Subjects

STANDARD model (Nuclear physics), STERILE neutrinos, PHYSICS, PARTICLE decays, DETECTORS, NEUTRINOS, SAND dunes, NEUTRINO detectors

Abstract

Next generation neutrino oscillation experiments like DUNE and T2HK are multi-purpose observatories, with a rich physics program beyond oscillation measurements. A special role is played by their near detector facilities, which are particularly well-suited to search for weakly coupled dark sector particles produced in the primary target. In this paper, we demonstrate this by estimating the sensitivity of the DUNE near detectors to the scattering of sub-GeV DM particles and to the decay of sub-GeV sterile neutrinos ("heavy neutral leptons"). We discuss in particular the importance of the DUNE-PRISM design, which allows some of the near detectors to be moved away from the beam axis. At such off-axis locations, the signal-to-background ratio improves for many new physics searches. We find that this leads to a dramatic boost in the sensitivity to boosted DM particles interacting mainly with hadrons, while for boosted DM interacting with leptons, data taken on-axis leads to marginally stronger exclusion limits. Searches for heavy neutral leptons perform equally well in both configurations. [ABSTRACT FROM AUTHOR]

Published

2022

6. Hilbert series for leptonic flavor invariants in the minimal seesaw model.

Author

Yu, Bingrong and Zhou, Shun

Subjects

NEUTRINO mass, STANDARD model (Nuclear physics), FLAVOR, ANTIMATTER, CP violation, NEUTRINOS

Abstract

In this paper, we examine the leptonic flavor invariants in the minimal see-saw model (MSM), in which only two right-handed neutrino singlets are added into the Standard Model in order to accommodate tiny neutrino masses and explain cosmological matter-antimatter asymmetry via leptogenesis mechanism. For the first time, we calculate the Hilbert series (HS) for the leptonic flavor invariants in the MSM. With the HS we demonstrate that there are totally 38 basic flavor invariants, among which 18 invariants are CP-odd and the others are CP-even. Moreover, we explicitly construct these basic invariants, and any other flavor invariants in the MSM can be decomposed into the polynomials of them. Interestingly, we find that any flavor invariants in the effective theory at the low-energy scale can be expressed as rational functions of those in the full MSM at the high-energy scale. Practical applications to the phenomenological studies of the MSM, such as the sufficient and necessary conditions for CP conservation and CP asymmetries in leptogenesis, are also briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2021

7. Complete one-loop matching of the type-I seesaw model onto the Standard Model effective field theory.

Author

Zhang, Di and Zhou, Shun

Subjects

STANDARD model (Nuclear physics), NEUTRINO mass, HERMITIAN structures, NEUTRINOS

Abstract

In this paper, we accomplish the complete one-loop matching of the type-I seesaw model onto the Standard Model Effective Field Theory (SMEFT), by integrating out three heavy Majorana neutrinos with the functional approach. It turns out that only 31 dimension-six operators (barring flavor structures and Hermitian conjugates) in the Warsaw basis of the SMEFT can be obtained, and most of them appear at the one-loop level. The Wilson coefficients of these 31 dimension-six operators are computed up to O (M−2) with M being the mass scale of heavy Majorana neutrinos. As the effects of heavy Majorana neutrinos are encoded in the Wilson coefficients of these higher-dimensional operators, a complete one-loop matching is useful to explore the low-energy phenomenological consequences of the type-I seesaw model. In addition, the threshold corrections to the couplings in the Standard Model and to the coefficient of the dimension-five operator are also discussed. [ABSTRACT FROM AUTHOR]

Published

2021

8. Unified emergence of energy scales and cosmic inflation.

Author

Kubo, Jisuke, Kuntz, Jeffrey, Lindner, Manfred, Rezacek, Jonas, Saake, Philipp, and Trautner, Andreas

Subjects

INFLATIONARY universe, STANDARD model (Nuclear physics), PLANCK scale, NEUTRINO mass, NEUTRINOS, SYMMETRY breaking

Abstract

In the quest for unification of the Standard Model with gravity, classical scale invariance can be utilized to dynamically generate the Planck mass MPl. However, the relation of Planck scale physics to the scale of electroweak symmetry breaking μH requires further explanation. In this paper, we propose a model that uses the spontaneous breaking of scale invariance in the scalar sector as a unified origin for dynamical generation of both scales. Using the Gildener-Weinberg approximation, only one scalar acquires a vacuum expectation value of υS ∼ (1016−17) GeV, thus radiatively generating M P 1 ≈ β S 1 / 2 υ S and μH via the neutrino option with right handed neutrino masses mN = yMυS ∼ 107 GeV. Consequently, active SM neutrinos are given a mass with the inclusion of a type-I seesaw mechanism. Furthermore, we adopt an unbroken Z2 symmetry and a Z2-odd set of right-handed Majorana neutrinos χ that do not take part in the neutrino option and are able to produce the correct dark matter relic abundance (dominantly) via inflaton decay. The model also describes cosmic inflation and the inflationary CMB observables are predicted to interpolate between those of R2 and linear chaotic inflationary model and are thus well within the strongest experimental constraints. [ABSTRACT FROM AUTHOR]

Published

2021

9. Naturally small Dirac neutrino mass with intermediate SU(2) multiplet fields.

Author

Wang, Weijian and Han, Zhi-Long

Subjects

NEUTRINO mass, DIRAC equation, FERMIONS, STANDARD model (Nuclear physics), DARK matter, PHENOMENOLOGICAL theory (Physics)

Abstract

If neutrinos are Dirac fermions, certain new physics beyond the standard model should exist to account for the smallness of neutrino mass. With two additional scalars and a heavy intermediate fermion, in this paper, we systematically study the general mechanism that can naturally generate the tiny Dirac neutrino mass at tree and in one-loop level. For tree level models, we focus on natural ones, in which the additional scalars develop small vacuum expectation values without fine-tuning. For one-loop level models, we explore those having dark matter candidates under Z symmetry. In both cases, we concentrate on SU(2) multiplet scalars no larger than quintuplet, and derive the complete sets of viable models. Phenomenologies, such as lepton flavor violation, leptogenesis, DM and LHC signatures are briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2017

10. On the systematic uncertainties in DUNE and their role in New Physics studies.

Author

Meloni, D.

Subjects

*UNCERTAINTY, *NEUTRINOS, *OSCILLATIONS, *QUANTUM gravity, *STANDARD model (Nuclear physics)

Abstract

In the recent years experiments have established the existence of neutrino os- cillations and most of the oscillation parameters have been measured with a good accuracy. The search for New Physics in neutrino oscillation will be an experimental concrete possi- bility in the next future. In this paper we investigate the ability of the DUNE facility to search for Non Standard Interaction (NSI) in neutrino propagation in matter, emphasizing the role of different assumptions on the shape and absolute normalization errors of both ve and vμ signals. We also study in detail the effects of NSI and systematics in the extraction of standard oscillation parameters. [ABSTRACT FROM AUTHOR]

Published

2018

11. The seesaw portal in testable models of neutrino masses.

Author

Caputo, A., Hernández, P., López-Pavón, J., and Salvado, J.

Subjects

*STANDARD model (Nuclear physics), *NEUTRINO mass, *MAJORANA fermions, *PARAMETER estimation, *HEAVY particles (Nuclear physics)

Abstract

A Standard Model extension with two Majorana neutrinos can explain the measured neutrino masses and mixings, and also account for the matter-antimatter asymmetry in a region of parameter space that could be testable in future experiments. The testability of the model relies to some extent on its minimality. In this paper we address the possibility that the model might be extended by extra generic new physics which we parametrize in terms of a low-energy effective theory. We consider the effects of the operators of the lowest dimensionality, d = 5, and evaluate the upper bounds on the coefficients so that the predictions of the minimal model are robust. One of the operators gives a new production mechanism for the heavy neutrinos at LHC via higgs decays. The higgs can decay to a pair of such neutrinos that, being long-lived, leave a powerful signal of two displaced vertices. We estimate the LHC reach to this process. [ABSTRACT FROM AUTHOR]

Published

2017

12. Model-independent constraints on non-unitary neutrino mixing from high-precision long-baseline experiments.

Author

Agarwalla, Sanjib Kumar, Das, Sudipta, Giarnetti, Alessio, and Meloni, Davide

Subjects

NEUTRINOS, SAND dunes, STANDARD model (Nuclear physics), DETECTORS

Abstract

Our knowledge on the active 3ν mixing angles (θ12, θ13, and θ23) and the CP phase δCP is becoming accurate day-by-day enabling us to test the unitarity of the leptonic mixing matrix with utmost precision. Future high-precision long-baseline experiments are going to play an important role in this direction. In this work, we study the impact of possible non-unitary neutrino mixing (NUNM) in the context of next-generation long-baseline experiments DUNE and T2HKK/JD+KD having one detector in Japan (T2HK/JD) and a second detector in Korea (KD). We estimate the sensitivities of these setups to place direct, model-independent, and competitive constraints on various NUNM parameters. We demonstrate the possible correlations between the NUNM parameters, θ23, and δCP. Our numerical results obtained using only far detector data and supported by simple approximate analytical expressions of the oscillation probabilities in matter, reveal that JD+KD has better sensitivities for |α21| and α22 as compared to DUNE, due to its larger statistics in the appearance channel and less systematic uncertainties in the disappearance channel, respectively. For |α31|, |α32|, and α33, DUNE gives better constraints as compared to JD+KD, due to its larger matter effect and wider neutrino energy spectrum. For α11, both DUNE and JD+KD give similar bounds. We also show how much the bounds on the NUNM parameters can be improved by combining the prospective data from DUNE and JD+KD setups. We find that due to zero-distance effects, the near detectors alone can also constrain α11, |α21|, and α22 in both these setups. Finally, we observe that the ντ appearance sample in DUNE can improve the constraints on |α32| and α33. [ABSTRACT FROM AUTHOR]

Published

2022

13. Novel constraints on neutrino physics beyond the standard model from the CONUS experiment.

Author

Bonet, H., Bonhomme, A., Buck, C., Fülber, K., Hakenmüller, J., Heusser, G., Hugle, T., Lindner, M., Maneschg, W., Rink, T., Strecker, H., and Wink, R.

Subjects

STANDARD model (Nuclear physics), CONSTRAINTS (Physics), NEUTRINOS, PARTICLE physics, NEUTRINO interactions, CONUS, COUPLING constants

Abstract

The measurements of coherent elastic neutrino-nucleus scattering (CEνNS) experiments have opened up the possibility to constrain neutrino physics beyond the standard model of elementary particle physics. Furthermore, by considering neutrino-electron scattering in the keV-energy region, it is possible to set additional limits on new physics processes. Here, we present constraints that are derived from Conus germanium data on beyond the standard model (BSM) processes like tensor and vector non-standard interactions (NSIs) in the neutrino-quark sector, as well as light vector and scalar mediators. Thanks to the realized low background levels in the Conus experiment at ionization energies below 1 keV, we are able to set the world's best limits on tensor NSIs from CEνNS and constrain the scale of corresponding new physics to lie above 360 GeV. For vector NSIs, the derived limits strongly depend on the assumed ionization quenching factor within the detector material, since small quenching factors largely suppress potential signals for both, the expected standard model CEνNS process and the vector NSIs. Furthermore, competitive limits on scalar and vector mediators are obtained from the CEνNS channel at reactor-site which allow to probe coupling constants as low as 5 ∙ 10−5 of low mediator masses, assuming the currently favored quenching factor regime. The consideration of neutrino-electron scatterings allows to set even stronger constraints for mediator masses below ∼ 1 MeV and ∼ 10 MeV for scalar and vector mediators, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

14. Searching for light new physics at the LHC via lepton-number violation.

Author

Bensalem, Wafia, London, David, Stolarski, Daniel, and Tonero, Alberto

Subjects

PHYSICS, LEPTONS (Nuclear physics), NEUTRINOS, QUARKS, STANDARD model (Nuclear physics)

Abstract

We study the collider phenomenology of a simplified model containing a right-handed W in which the WR couples predominantly to the third generation in the quark sector. The model also includes a light Majorana neutrino, with M1 ∼ O 100 GeV, giving rise to lepton-number-violating signatures that are visible at the LHC. Taking into account all the searches from the LHC and Tevatron, we find that this WR can still be as light as MR ∼ 300 GeV. We show that this type of new physics, and others like it, can be detected at the LHC using final states with three same-sign same-flavour leptons. [ABSTRACT FROM AUTHOR]

Published

2022

15. Future DUNE constraints on EFT.

Author

Falkowski, Adam, Grilli di Cortona, Giovanni, and Tabrizi, Zahra

Subjects

STANDARD model (Nuclear physics), PARTICLES (Nuclear physics), HIGGS bosons, PARTICLE physics, NEUTRINOS, SCATTERING (Physics)

Abstract

In the near future, fundamental interactions at high-energy scales may be most efficiently studied via precision measurements at low energies. A universal language to assemble and interpret precision measurements is the so-called SMEFT, which is an effective field theory (EFT) where the Standard Model (SM) Lagrangian is extended by higher-dimensional operators. In this paper we investigate the possible impact of the DUNE neutrino experiment on constraining the SMEFT. The unprecedented neutrino flux offers an opportunity to greatly improve the current limits via precision measurements of the trident production and neutrino scattering off electrons and nuclei in the DUNE near detector. We quantify the DUNE sensitivity to dimension-6 operators in the SMEFT Lagrangian, and find that in some cases operators suppressed by an O30 TeV scale can be probed. We also compare the DUNE reach to that of future experiments involving atomic parity violation and polarization asymmetry in electron scattering, which are sensitive to an overlapping set of SMEFT parameters. [ABSTRACT FROM AUTHOR]

Published

2018

16. CP violation in the rare Higgs decays via exchange of on-shell almost degenerate Majorana neutrinos, H→vkNj→vkℓ−UD¯ and H→vkNj→vkℓ+U¯D.

Author

Cvetič, Gorazd, Kim, C. S., and Zamora-Saá, Jiberto

Subjects

NEUTRINOS, CP violation, HIGGS bosons, QUARK decay, STANDARD model (Nuclear physics), QUARKS

Abstract

We investigate rare decays of Higgs via exchange of two almost degenerate heavy on-shell Majorana neutrinos Nj (j = 1, 2): Γ± = Γ(h → νkNj→ νkℓ±π∓), and into the open quark channels Γ± = Γ(h → νkNj→ νkℓ±UD), where UD are two jets of open quarks ( U ¯ D , or U D ¯ , where U = u, c and D = d, s). The related CP violation asymmetry ACP = (Γ−− Γ+)/(Γ− + Γ+) is studied in detail. We take into account the N1-N2 overlap and oscillation effects. We can see that for certain, presently acceptable, range of input parameters, such decays with open quark channels, and their asymmetries, could be detected in the International Linear Collider (ILC). [ABSTRACT FROM AUTHOR]

Published

2022

17. Unstable cosmic neutrino capture.

Author

Akita, Kensuke, Lambiase, Gaetano, and Yamaguchi, Masahide

Subjects

NEUTRINOS, STANDARD model (Nuclear physics), TRITIUM

Abstract

Future direct observations of the Cosmic Neutrino Background (CνB) have the potential to explore a neutrino lifetime, especially in the region of the age of the universe, t0 = 4.35 × 1017 s. We forecast constraints on neutrino decay via capture of the CνB on tritium, with emphasis on the PTOLEMY-type experiment. In addition, in some cases of invisible neutrino decay into lighter neutrinos in the Standard Model and invisible particles, we can constrain not only the neutrino lifetime but also the masses of the invisible particles. For this purpose, we also formulate the energy spectra of the lighter neutrinos produced by 2-body and 3-body decays, and those of the electrons emitted in the process of the detection of the lighter neutrinos. [ABSTRACT FROM AUTHOR]

Published

2022

18. Fermion mass hierarchy and g − 2 anomalies in an extended 3HDM Model.

Author

Hernández, A. E. Cárcamo, Kovalenko, Sergey, Maniatis, M., and Schmidt, Ivan

Subjects

FERMIONS, MAJORANA fermions, STANDARD model (Nuclear physics), QUARKS, MUONS, MAGNETIC moments, HIGGS bosons

Abstract

We propose an extension of the three-Higgs-doublet model (3HDM), where the Standard Model (SM) particle content is enlarged by the inclusion of two inert SU2L scalar doublets, three inert and two active electrically neutral gauge singlet scalars, charged vector like fermions and Majorana neutrinos. These additional particles are introduced to generate the SM fermion mass hierarchy from a sequential loop suppression mechanism. In our model the top and exotic fermion masses appear at tree level, whereas the remaining fermions get their masses radiatively. Specifically, bottom, charm, tau and muon masses appear at 1-loop; the masses for the light up, down and strange quarks as well as for the electron at 2-loop and masses for the light active neutrinos at 3-loop. Our model successfully accounts for SM fermion masses and mixings and accommodates the observed Dark Matter relic density, the electron and muon anomalous magnetic moments, as well the constraints arising from charged Lepton Flavor Violating (LFV) processes. The proposed model predicts charged LFV decays within the reach of forthcoming experiments. [ABSTRACT FROM AUTHOR]

Published

2021

19. Charged Higgs effects in IceCube: PeV events and NSIs.

Author

Dey, Ujjal Kumar, Nath, Newton, and Sadhukhan, Soumya

Subjects

NEUTRINO detectors, NEUTRINO interactions, NEUTRINOS, STANDARD model (Nuclear physics), HIGGS bosons

Abstract

Extensions of the Standard Model with charged Higgs, having a non-negligible coupling with neutrinos, can have interesting implications vis-à-vis neutrino experiments. Such models can leave their footprints not only in the ultra-high energy neutrino detectors like IceCube but can also give rise to the neutrino non-standard interactions (NSIs). We consider a model based on the neutrinophilic two-Higgs doublets and study its imprints in the excess neutrino events in the 1–3 PeV energy bins at the IceCube. This is facilitated by the existence of a charged scalar in the model which can result in a Glashow-like resonance. The same charged scalar can be responsible for sizeable NSIs. We perform a combined study of the latest IceCube data along with various other constraints arising from different neutrino experiments together with the limits set by the LEP experiment, and explore the parameter space which can lead to a sizeable NSI. [ABSTRACT FROM AUTHOR]

Published

2021

20. One colorful resolution to the neutrino mass generation, three lepton flavor universality anomalies, and the Cabibbo angle anomaly.

Author

Chang, We-Fu

Subjects

NEUTRINO mass, BARYON number, NEUTRINOS, LEPTONS (Nuclear physics), MAGNETIC dipole moments, STANDARD model (Nuclear physics), MULTI-degree of freedom, NEUTRINO oscillation

Abstract

We propose a simple model to simultaneously explain four observed flavor anomalies while generating the neutrino mass at the one-loop level. Specifically, we address the measured anomalous magnetic dipole moments of the muon, ∆aμ, and electron, ∆ae, the observed anomaly of b → sl+l− in the B-meson decays, and the Cabibbo-angle anomaly. The model consists of four colorful new degrees of freedom: three scalar leptoquarks with the Standard Model quantum numbers (3, 3, −1/3), (3, 2, 1/6), and (3, 1, 2/3), and one pair of down-quark-like vector fermion in (3, 1, −1/3). The baryon number is assumed to be conserved for simplicity. Phenomenologically viable solutions with the minimal number of real parameters can be found to accommodate all the above-mentioned anomalies and produce the approximate, close to 1σ, neutrino oscillation pattern at the same time. From general consideration, the model robustly predicts: (1) neutrino mass is of the normal hierarchy type, and (2) M ee ν ≲ 3 × 10−4 MeV. The possible UV origin to explain the flavor pattern of the found viable parameter space is briefly discussed. The parameter space can be well reproduced within a simple split fermion toy model. [ABSTRACT FROM AUTHOR]

Published

2021

21. Heavy neutral leptons in effective field theory and the high-luminosity LHC.

Author

Cottin, Giovanna, Helo, Juan Carlos, Hirsch, Martin, Titov, Arsenii, and Wang, Zeren Simon

Subjects

STANDARD model (Nuclear physics), NEUTRINO mass, ELECTROWEAK interactions, NEUTRINOS, FERMIONS

Abstract

Heavy neutral leptons (HNLs) with masses around the electroweak scale are expected to be rather long-lived particles, as a result of the observed smallness of the active neutrino masses. In this work, we study long-lived HNLs in NRSMEFT, a Standard Model (SM) extension with singlet fermions to which we add non-renormalizable operators up to dimension-6. Operators which contain two HNLs can lead to a sizable enhancement of the production cross sections, compared to the minimal case where HNLs are produced only via their mixing with the SM neutrinos. We calculate the expected sensitivities for the ATLAS detector and the future far-detector experiments: AL3X, ANUBIS, CODEX-b, FASER, MATHUSLA, and MoEDAL-MAPP in this setup. The sensitive ranges of the HNL mass and of the active-heavy mixing angle are much larger than those in the minimal case. We study both, Dirac and Majorana, HNLs and discuss how the two cases actually differ phenomenologically, for HNL masses above roughly 100 GeV. [ABSTRACT FROM AUTHOR]

Published

2021

22. Time-delayed electrons from neutral currents at the LHC.

Author

Cheung, Kingman, Wang, Kechen, and Wang, Zeren Simon

Subjects

PARTICLE detectors, SUPERSYMMETRY, STANDARD model (Nuclear physics), GAUGE bosons, SPACE probes, ELECTRONS, NEUTRALINOS, PROTON-proton interactions

Abstract

We investigate long-lived particles (LLPs) produced in pair from neutral currents and decaying into a displaced electron plus two jets at the LHC, utilizing the proposed minimum ionizing particle timing detector at CMS. We study two benchmark models: the R-parity-violating supersymmetry with the lightest neutralinos being the lightest supersymmetric particle and two different U(1) extensions of the standard model with heavy neutral leptons (HNLs). The light neutralinos are produced from the standard model Z-boson decays via small Higgsino components, and the HNLs arise from decays of a heavy gauge boson, Z′. By simulating the signal processes at the HL-LHC with the center-of-mass energy s = 14 TeV and integrated luminosity of 3 ab−1, our analyses indicate that the search strategy based on a timing trigger and the final state kinematics has the potential to probe the parameter space that is complementary to other traditional LLP search strategies such as those based on the displaced vertex. [ABSTRACT FROM AUTHOR]

Published

2021

23. Leptonic anomalous magnetic moments in ν SMEFT.

Author

Cirigliano, Vincenzo, Dekens, Wouter, de Vries, Jordy, Fuyuto, Kaori, Mereghetti, Emanuele, and Ruiz, Richard

Subjects

NEUTRINOLESS double beta decay, MAGNETIC moments, STERILE neutrinos, CKM matrix, STANDARD model (Nuclear physics), NEUTRINO mass

Abstract

We investigate contributions to the anomalous magnetic moments of charged leptons in the neutrino-extended Standard Model Effective Field Theory (νSMEFT). We discuss how νSMEFT operators can contribute to a lepton's magnetic moment at one- and two-loop order. We show that only one operator can account for existing electronic and muonic discrepancies, assuming new physics appears above 1 TeV. In particular, we find that a right-handed charged current in combination with minimal sterile-active mixing can explain the discrepancy for sterile neutrino masses of O (100) GeV while avoiding direct and indirect constraints. We discuss how searches for sterile neutrino production at the (HL-)LHC, measurements of h→μ+μ− and searches for h→e+e−, neutrinoless double beta decay experiments, and improved unitarity tests of the CKM matrix can further probe the relevant parameter space. [ABSTRACT FROM AUTHOR]

Published

2021

24. An allowed window for heavy neutral leptons below the kaon mass.

Author

Bondarenko, Kyrylo, Boyarsky, Alexey, Klaric, Juraj, Mikulenko, Oleksii, Ruchayskiy, Oleg, Syvolap, Vsevolod, and Timiryasov, Inar

Subjects

NEUTRINO mass, STANDARD model (Nuclear physics), NEUTRINO oscillation, MAJORANA fermions, NEUTRINOS, NUCLEOSYNTHESIS, SAND dunes

Abstract

The extension of the Standard Model with two gauge-singlet Majorana fermions can simultaneously explain two beyond-the-Standard-model phenomena: neutrino masses and oscillations, as well as the origin of the matter-antimatter asymmetry in the Universe. The parameters of such a model are constrained by the neutrino oscillation data, direct accelerator searches, big bang nucleosynthesis, and requirement of successful baryogenesis. We show that their combination still leaves an allowed region in the parameter space below the kaon mass. This region can be probed by the further searches of NA62, DUNE, or SHiP experiments. [ABSTRACT FROM AUTHOR]

Published

2021

25. On the τ flavor of the cosmic neutrino flux.

Author

Farzan, Yasaman

Subjects

NEUTRINOS, NEUTRINO interactions, STANDARD model (Nuclear physics), FLAVOR, RADIO telescopes, DARK matter

Abstract

Observation of high energy cosmic neutrinos by ICECUBE has ushered in a new era in exploring both cosmos and new physics beyond the Standard Model (SM). In the standard picture, although mostly νμ and νe are produced in the source, oscillation will produce ντen route. Certain beyond SM scenarios, like interaction with ultralight DM can alter this picture. Thus, the flavor composition of the cosmic neutrino flux can open up the possibility of exploring certain beyond the SM scenarios that are inaccessible otherwise. We show that the τ flavor holds a special place among the neutrino flavors in elucidating new physics. Interpreting the two anomalous events observed by ANITA as ντ events makes the tau flavor even more intriguing. We study how the detection of the two tau events by ICECUBE constrains the interaction of the neutrinos with ultralight dark matter and discuss the implications of this interaction for even higher energy cosmic neutrinos detectable by future radio telescopes such as ARA, ARIANNA and GRAND. We also revisit the 3 + 1 neutrino scheme as a solution to the two anomalous ANITA events and clarify a misconception that exists in the literature about the evolution of high energy neutrinos in matter within the 3 + 1 scheme with a possibility of scattering off nuclei. We show that the existing bounds on the flux of ντ with energy of EeV rules out this solution for the ANITA events. We show that the 3 + 1 solution can be saved from both this bound and from the bound on the extra relativistic degrees of freedom in the early universe by turning on the interaction of neutrinos with ultralight dark matter. [ABSTRACT FROM AUTHOR]

Published

2021

26. Light, long-lived B − L gauge and Higgs bosons at the DUNE near detector.

Author

Bhupal Dev, P. S., Dutta, Bhaskar, Kelly, Kevin J., Mohapatra, Rabindra N., and Zhang, Yongchao

Subjects

SAND dunes, STANDARD model (Nuclear physics), Z bosons, GAUGE bosons, GAUGE symmetries, NEUTRINO mass, HIGGS bosons

Abstract

The low-energy U(1)B−L gauge symmetry is well-motivated as part of beyond Standard Model physics related to neutrino mass generation. We show that a light B − L gauge boson Z′ and the associated U(1)B−L-breaking scalar φ can both be effectively searched for at high-intensity facilities such as the near detector complex of the Deep Underground Neutrino Experiment (DUNE). Without the scalar φ, the Z′ can be probed at DUNE up to mass of 1 GeV, with the corresponding gauge coupling gBL as low as 10−9. In the presence of the scalar φ with gauge coupling to Z′, the DUNE capability of discovering the gauge boson Z′ can be significantly improved, even by one order of magnitude in gBL, due to additional production from the decay φ → Z′Z′. The DUNE sensitivity is largely complementary to other long-lived Z′ searches at beam-dump facilities such as FASER and SHiP, as well as astrophysical and cosmological probes. On the other hand, the prospects of detecting φ itself at DUNE are to some extent weakened in presence of Z′, compared to the case without the gauge interaction. [ABSTRACT FROM AUTHOR]

Published

2021

27. Dynamical inverse seesaw mechanism as a simple benchmark for electroweak breaking and Higgs boson studies.

Author

Mandal, Sanjoy, Romão, Jorge C., Srivastava, Rahul, and Valle, José W. F.

Subjects

HIGGS bosons, ELECTROWEAK interactions, LEPTON number, STANDARD model (Nuclear physics), NAMBU-Goldstone bosons, NEUTRINO mass

Abstract

The Standard Model (SM) vacuum is unstable for the measured values of the top Yukawa coupling and Higgs mass. Here we study the issue of vacuum stability when neutrino masses are generated through spontaneous low-scale lepton number violation. In the simplest dynamical inverse seesaw, the SM Higgs has two siblings: a massive CP-even scalar plus a massless Nambu-Goldstone boson, called majoron. For TeV scale breaking of lepton number, Higgs bosons can have a sizeable decay into the invisible majorons. We examine the interplay and complementarity of vacuum stability and perturbativity restrictions, with collider constraints on visible and invisible Higgs boson decay channels. This simple framework may help guiding further studies, for example, at the proposed FCC facility. [ABSTRACT FROM AUTHOR]

Published

2021

28. Controlled fermion mixing and FCNCs in a ∆(27) 3+1 Higgs Doublet Model.

Author

Cárcamo Hernández, A. E., de Medeiros Varzielas, Ivo, López-Ibáñez, M. L., and Melis, Aurora

Subjects

NEUTRINO mass, DISCRETE symmetries, FERMIONS, STANDARD model (Nuclear physics), NEUTRINOS, NEUTRINO oscillation, DARK matter

Abstract

We propose a 3+1 Higgs Doublet Model based on the ∆(27) family symmetry supplemented by several auxiliary cyclic symmetries leading to viable Yukawa textures for the Standard Model fermions, consistent with the observed pattern of fermion masses and mixings. The charged fermion mass hierarchy and the quark mixing pattern is generated by the spontaneous breaking of the discrete symmetries due to flavons that act as Froggatt-Nielsen fields. The tiny neutrino masses arise from a radiative seesaw mechanism at one loop level, thanks to a preserved Z 2 1 discrete symmetry, which also leads to stable scalar and fermionic dark matter candidates. The leptonic sector features the predictive cobimaximal mixing pattern, consistent with the experimental data from neutrino oscillations. For the scenario of normal neutrino mass hierarchy, the model predicts an effective Majorana neutrino mass parameter in the range 3 meV ≲ mββ ≲ 18 meV, which is within the declared range of sensitivity of modern experiments. The model predicts Flavour Changing Neutral Currents which constrain the model, for instance, μ→e nuclear conversion processes and Kaon mixing are found to be within the reach of the forthcoming experiments. [ABSTRACT FROM AUTHOR]

Published

2021

29. Relativistic freeze-in with scalar dark matter in a gauged B − L model and electroweak symmetry breaking.

Author

Bandyopadhyay, Priyotosh, Mitra, Manimala, and Roy, Abhishek

Subjects

DARK matter, ELECTROWEAK interactions, SYMMETRY breaking, HIGGS bosons, GAGING, STANDARD model (Nuclear physics)

Abstract

We explore relativistic freeze-in production of scalar dark matter in gauged B − L model, where we focus on the production of dark matter from the decay and annihilation of Standard Model (SM) and B − L Higgs bosons. We consider the Bose-Einstein (BE) and Fermi-Dirac (FD) statistics, along with the thermal mass correction of the SM Higgs boson in our analysis. We show that in addition to the SM Higgs boson, the annihilation and decay of the B − L scalar can also contribute substantially to the dark matter relic density. Potential effects of electroweak symmetry breaking (EWSB) and thermal mass correction in BE framework enhance the dark matter relic substantially as it freezes-in near EWSB temperature via scalar annihilation. However, such effects are not so prominent when the dark matter freezes-in at a later epoch than EWSB, dominantly by decay of scalars. The results of this analysis are rather generic, and applicable to other similar scenarios. [ABSTRACT FROM AUTHOR]

Published

2021

30. Neutrino non-standard interactions meet precision measurements of Neff.

Author

Du, Yong and Yu, Jiang-Hao

Subjects

NEUTRINO interactions, NEUTRINOS, DEEP inelastic collisions, STANDARD model (Nuclear physics), NEUTRINO scattering, NEUTRINO oscillation

Abstract

The number of relativistic species, Neff, has been precisely calculated in the standard model, and would be measured to the percent level by CMB-S4 in future. Neutral-current non-standard interactions would affect neutrino decoupling in the early Universe, thus modifying Neff. We parameterize those operators up to dimension-7 in the effective field theory framework, and then provide a complete, generic and analytical dictionary for the collision term integrals. From precision measurements of Neff, the most stringent constraint is obtained for the dimension-6 vector-type neutrino-electron operator, whose scale is constrained to be above about 195 (331) GeV from Planck (CMB-S4). We find our results complementary to other experiments like neutrino coherent scattering, neutrino oscillation, collider, and neutrino deep inelastic scattering experiments. [ABSTRACT FROM AUTHOR]

Published

2021

31. Anomalous dimensions from Yukawa couplings in SMNEFT: four-fermion operators.

Author

Datta, Alakabha, Kumar, Jacky, Liu, Hongkai, and Marfatia, Danny

Subjects

STANDARD model (Nuclear physics), NEUTRINOS, COUPLES

Abstract

The Standard Model Neutrino Effective Field Theory (SMNEFT) is the Standard Model Effective Field Theory (SMEFT) augmented with right-handed neutrinos. Building on our previous work, arXiv:2010.12109, we calculate the Yukawa coupling contributions to the one-loop anomalous dimension matrix for the 11 dimension-six four-fermion SMNEFT operators. We also present the new contributions to the anomalous dimension matrix for the 14 four-fermion SMEFT operators that mix with the SMNEFT operators through the Yukawa couplings of the right-handed neutrinos. [ABSTRACT FROM AUTHOR]

Published

2021

32. Minimal inverse-seesaw mechanism with Abelian flavour symmetries.

Author

Câmara, H. B., Felipe, R. G., and Joaquim, F. R.

Subjects

STERILE neutrinos, CP violation, BRANCHING ratios, STANDARD model (Nuclear physics), NEUTRINO mass

Abstract

We study the phenomenology of the minimal (2, 2) inverse-seesaw model supplemented with Abelian flavour symmetries. To ensure maximal predictability, we establish the most restrictive flavour patterns which can be realised by those symmetries. This setup requires adding an extra scalar doublet and two complex scalar singlets to the Standard Model, paving the way to implement spontaneous CP violation. It is shown that such CP-violating effects can be successfully communicated to the lepton sector through couplings of the scalar singlets to the new sterile fermions. The Majorana and Dirac CP phases turn out to be related, and the active-sterile neutrino mixing is determined by the active neutrino masses, mixing angles and CP phases. We investigate the constraints imposed on the model by the current experimental limits on lepton flavour-violating decays, especially those on the branching ratio BR(μ → eγ) and the capture rate CR(μ − e, Au). The prospects to further test the framework put forward in this work are also discussed in view of the projected sensitivities of future experimental searches sensitive to the presence of heavy sterile neutrinos. Namely, we investigate at which extent upcoming searches for μ → eγ, μ → 3e and μ − e conversion in nuclei will be able to test our model, and how complementary will future high-energy collider and beam-dump experiments be in that task. [ABSTRACT FROM AUTHOR]

Published

2021

33. Long-lived biνo at the LHC.

Author

Gehrlein, Julia and Ipek, Seyda

Subjects

PARTICLE detectors, STANDARD model (Nuclear physics), QUARK decay, SUPERSYMMETRY, NEUTRINOS, DETECTORS, NEUTRINO mass

Abstract

We examine the detection prospects for a long-lived biνo, a pseudo-Dirac bino which is responsible for neutrino masses, at the LHC and at dedicated long-lived particle detectors. The biνo arises in U(1)R-symmetric supersymmetric models where the neutrino masses are generated through higher dimensional operators in an inverse seesaw mechanism. At the LHC the biνo is produced through squark decays and it subsequently decays to quarks, charged leptons and missing energy via its mixing with the Standard Model neutrinos. We consider long-lived biνos which escape the ATLAS or CMS detectors as missing energy and decay to charged leptons inside the proposed long-lived particle detectors FASER, CODEX-b, and MATHUSLA. We find the currently allowed region in the squark-biνo mass parameter space by recasting most recent LHC searches for jets+. We also determine the reach of MATHUSLA, CODEX-b and FASER. We find that a large region of parameter space involving squark masses, biνo mass and the messenger scale can be probed with MATHUSLA, ranging from biνo masses of 10 GeV-2 TeV and messenger scales 102−11 TeV for a range of squark masses. [ABSTRACT FROM AUTHOR]

Published

2021

34. Exploring charm decays with missing energy in leptoquark models.

Author

Faisel, Gaber, Su, Jhih-Ying, and Tandean, Jusak

Subjects

NEUTRINO interactions, STERILE neutrinos, STANDARD model (Nuclear physics), BARYON decay, MESON decay, MESONS, NEUTRINOS

Abstract

We investigate the possibility that scalar leptoquarks generate consequential effects on the flavor-changing neutral-current decays of charmed hadrons into final states with missing energy carried away by either standard model or sterile neutrinos. We focus on scenarios involving the R2, R ˜ 2 , and S ¯ 1 leptoquarks and take into account various pertinent constraints, learning that meson-mixing ones and those inferred from collider searches can be of significance. We find in particular that the branching fractions of charmed meson decays D → , M = π, ρ, and Ds→ and singly charmed baryon decays Λ c + → and Ξc→ are presently allowed to attain the 10−7-10−6 levels if induced by R2 and that the impact of R ˜ 2 is comparatively much less. In contrast, the contributions of S ¯ 1 , which couples to right-handed up-type quarks and the sterile neutrinos, could lead to branching fractions as high as order 10−3. This suggests that these charmed hadron decays might be within reach of the BESIII and Belle II experiments or future super charm-tau factories and could serve as potentially promising probes of leptoquark interactions with sterile neutrinos. [ABSTRACT FROM AUTHOR]

Published

2021

35. Electroweak symmetry breaking in the inverse seesaw mechanism.

Author

Mandal, Sanjoy, Srivastava, Rahul, and Valle, José W. F.

Subjects

SYMMETRY breaking, ELECTROWEAK interactions, STANDARD model (Nuclear physics), LEPTON number, PLANCK scale, MODELS & modelmaking

Abstract

We investigate the stability of Higgs potential in inverse seesaw models. We derive the full two-loop RGEs of the relevant parameters, such as the quartic Higgs self-coupling, taking thresholds into account. We find that for relatively large Yukawa couplings the Higgs quartic self-coupling goes negative well below the Standard Model instability scale ∼ 1010 GeV. We show, however, that the "dynamical" inverse seesaw with spontaneous lepton number violation can lead to a completely consistent and stable Higgs vacuum up to the Planck scale. [ABSTRACT FROM AUTHOR]

Published

2021

36. Relativistic impulse approximation in the atomic ionization process induced by millicharged particles.

Author

Qiao, Chen-Kai, Lin, Shin-Ted, Chi, Hsin-Chang, and Jia, Hai-Tao

Subjects

NEUTRINOS, DIFFERENTIAL cross sections, STANDARD model (Nuclear physics), GERMANIUM radiation detectors, DARK matter, SOLAR neutrinos

Abstract

The millicharged particle has become an attractive topic to probe physics beyond the Standard Model. In direct detection experiments, the parameter space of millicharged particles can be constrained from the atomic ionization process. In this work, we develop the relativistic impulse approximation (RIA) approach, which can duel with atomic many-body effects effectively, in the atomic ionization process induced by millicharged particles. The formulation of RIA in the atomic ionization induced by millicharged particles is derived, and the numerical calculations are obtained and compared with those from free electron approximation and equivalent photon approximation. Concretely, the atomic ionizations induced by mllicharged dark matter particles and millicharged neutrinos in high-purity germanium (HPGe) and liquid xenon (LXe) detectors are carefully studied in this work. The differential cross sections, reaction event rates in HPGe and LXe detectors, and detecting sensitivities on dark matter particle and neutrino millicharge in next-generation HPGe and LXe based experiments are estimated and calculated to give a comprehensive study. Our results suggested that the next-generation experiments would improve 2-3 orders of magnitude on dark matter particle millicharge δχ than the current best experimental bounds in direct detection experiments. Furthermore, the next-generation experiments would also improve 2-3 times on neutrino millicharge δν than the current experimental bounds. [ABSTRACT FROM AUTHOR]

Published

2021

37. The see-saw portal at future Higgs Factories.

Author

Barducci, Daniele, Bertuzzo, Enrico, Caputo, Andrea, Hernandez, Pilar, and Mele, Barbara

Subjects

ELECTROWEAK interactions, STANDARD model (Nuclear physics), Z bosons, NEUTRINO mass, HIGGS bosons, CENTER of mass

Abstract

We consider an extension of the Standard Model with two right-handed singlet fermions with mass at the electroweak scale that induce neutrino masses, plus a generic new physics sector at a higher scale Λ. We focus on the effective operators of lowest dimension d = 5, which induce new production and decay modes for the singlet fermions. We assess the sensitivity of future Higgs Factories, such as FCC-ee, CLIC-380, ILC and CEPC, to the coefficients of these operators for various center of mass energies. We show that future lepton colliders can test the cut-off of the theory up to Λ ≃ 500–1000 TeV, surpassing the reach of future indirect measurements of the Higgs and Z boson widths. We also comment on the possibility of determining the underlying model flavor structure should a New Physics signal be observed, and on the impact of higher dimensional d = 6 operators on the experimental signatures. [ABSTRACT FROM AUTHOR]

Published

2021

38. Understanding the MiniBooNE and the muon and electron g − 2 anomalies with a light Z′ and a second Higgs doublet.

Author

Abdallah, Waleed, Gandhi, Raj, and Roy, Samiran

Subjects

STANDARD model (Nuclear physics), MUONS, ELECTRONS, HIGGS bosons, ANGULAR distribution (Nuclear physics), NEUTRINOS, GAUGE bosons

Abstract

Two of the most widely studied extensions of the Standard Model (SM) are a) the addition of a new U(1) symmetry to its existing gauge groups, and b) the expansion of its scalar sector to incorporate a second Higgs doublet. We show that when combined, they allow us to understand the electron-like event excess seen in the MiniBooNE (MB) experiment as well as account for the observed anomalous values of the muon magnetic moment. A light Z′ associated with an additional U(1) coupled to baryons and to the dark sector, with flavor non-universal couplings to leptons, in conjunction with a second Higgs doublet is capable of explaining the MB excess. The Z′ obtains its mass from a dark singlet scalar, which mixes with the two Higgs doublets. Choosing benchmark parameter values, we show that U 1 B − 3 L τ , which is anomaly-free, and U(1)B, both provide (phenomenologically) equally good solutions to the excess. We also point out the other (anomaly-free) U(1) choices that may be possible upon fuller exploration of the parameter space. We obtain very good matches to the energy and angular distributions for neutrinos and anti-neutrinos in MB. The extended Higgs sector has two light CP-even scalars, h′ and H , and their masses and couplings are such that in principle, both contribute to help explain the MB excess as well as the present observed values of the muon and electron g − 2. We discuss the constraints on our model as well as future tests. Our work underlines the role that light scalars may play in understanding present-day low-energy anomalies. It also points to the possible existence of portals to the dark sector, i.e., a light gauge boson field (Z′) and a dark neutrino which mixes with the active neutrinos, as well as a dark sector light scalar which mixes with the extended Higgs sector. [ABSTRACT FROM AUTHOR]

Published

2020

39. An explicit construction of the dimension-9 operator basis in the standard model effective field theory.

Author

Liao, Yi and Ma, Xiao-Dong

Subjects

BARYON number, LEPTON number, STANDARD model (Nuclear physics), HERMITIAN operators, EQUATIONS of motion, GAUGE symmetries

Abstract

We investigate systematically dimension-9 operators in the standard model effective field theory which contains only standard model fields and respects its gauge symmetry. With the help of the Hilbert series approach to classifying operators according to their lepton and baryon numbers and their field contents, we construct the basis of operators explicitly. We remove redundant operators by employing various kinematic and algebraic relations including integration by parts, equations of motion, Schouten identities, Dirac matrix and Fierz identities, and Bianchi identities. We confirm counting of independent operators by analyzing their flavor symmetry relations. All operators violate lepton or baryon number or both, and are thus non-Hermitian. Including Hermitian conjugated operators there are 384 Δ B = 0 Δ L = ± 2 + 10 Δ B = ± 2 Δ L = 0 + 4 Δ B = ± 1 Δ L = ± 3 + 236 Δ B = ± 1 Δ L = ∓ 1 operators without referring to fermion generations, and 44874 Δ B = 0 Δ L = ± 2 + 2862 Δ B = ± 2 Δ L = 0 + 486 Δ B = ± 1 Δ L = ± 3 + 42234 Δ B = ∓ 1 Δ L = ± 1 operators when three generations of fermions are referred to, where ∆L, ∆B denote the net lepton and baryon numbers of the operators. Our result provides a starting point for consistent phenomenological studies associated with dimension-9 operators. [ABSTRACT FROM AUTHOR]

Published

2020

40. Lepton number violating operators with standard model gauge fields: a survey of neutrino masses from 3-loops and their link to dark matter.

Author

Gustafsson, Michael, No, José Miguel, and Rivera, Maximiliano A.

Subjects

STANDARD model (Nuclear physics), LEPTON number, DARK matter, NEUTRINO mass, LEPTONS (Nuclear physics), ELECTROWEAK interactions, PHYSICS, NEUTRINOS

Abstract

We investigate neutrino mass generation scenarios where the lepton number breaking new physics does not interact with Standard Model (SM) quarks and couples only to the SM right-handed charged lepton chirality. The lowest-order lepton number violating effective operator which describes this framework is a unique dimension nine operator involving SM gauge fields, O 9 . We find that there are two possible classes of new physics scenarios giving rise to this O 9 operator. In these scenarios neutrino masses are induced radiatively via dark matter interactions, linking the dark matter to a natural explanation for the smallness of neutrino masses compared to the electroweak scale. We discuss the phenomenology and existing constraints in the different neutrino mass models within each class. In particular, we analyze the important interplay between neutrino mixing and neutrinoless double β-decay in order to predict characteristic signatures and disfavour certain scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

41. Probing energetic light dark matter with multi-particle tracks signatures at DUNE.

Author

De Roeck, Albert, Kim, Doojin, Moghaddam, Zahra Gh., Park, Jong-Chul, Shin, Seodong, and Whitehead, Leigh H.

Subjects

DARK matter, STANDARD model (Nuclear physics), SAND dunes, LIQUID argon, WEAKLY interacting massive particles, NEUTRINOS, MOTIVATION (Psychology), DETECTORS

Abstract

The search for relativistic scattering signals of cosmogenic light dark matter at terrestrial detectors has received increasing attention as an alternative approach to probe dark-sector physics. Large-volume neutrino experiments are well motivated for searches of dark matter that interacts very weakly with Standard Model particles and/or that exhibits a small incoming flux. We perform a dedicated signal sensitivity study for a detector similar to the one proposed by the DUNE Collaboration for cosmogenic dark-matter signals resulting from a non-minimal multi-particle dark-sector scenario. The liquid argon time projection chamber technology adopted for the DUNE detectors is particularly suited for searching for complicated signatures owing to good measurement resolution and particle identification, as well as dE/dx measurements to recognize merged tracks. Taking inelastic boosted dark matter as our benchmark scenario that allows for multiple visible particles in the final state, we demonstrate that the DUNE far detectors have a great potential for probing scattering signals induced by relativistic light dark matter. Detector effects and backgrounds have been estimated and taken into account. Model-dependent and model-independent expected sensitivity limits for a DUNE-like detector are presented. [ABSTRACT FROM AUTHOR]

Published

2020

42. One-loop matching in the SMEFT extended with a sterile neutrino.

Author

Chala, Mikael and Titov, Arsenii

Subjects

STERILE neutrinos, OPERATOR equations, EQUATIONS of motion, NEUTRINOS, STANDARD model (Nuclear physics), MODEL theory

Abstract

We study the phenomenology of the simplest renormalisable model that, at low energy, leads to the effective field theory of the Standard Model extended with right-handed neutrinos (νSMEFT). Our aim is twofold. First, to contextualise new collider signatures in models with sterile neutrinos so far studied only using the bottom-up approach. And second and more important, to provide a thorough example of one-loop matching in the diagrammatic approach, of which other matching techniques and automatic tools can benefit for cross-checks. As byproducts of this work, we provide for the first time: (i) a complete off-shell basis for the νSMEFT and explicit relations between operators linked by equations of motion; (ii) a complete basis for the low-energy effective field theory (νLEFT) and the tree-level matching onto the νSMEFT; (iii) partial one-loop anomalous dimensions in the νLEFT. This way, our work comprises a new step forward towards the systematisation of one-loop computations in effective field theories, especially if the SM neutrinos are Dirac. [ABSTRACT FROM AUTHOR]

Published

2020

43. Addendum to “Compact perturbative expressions for neutrino oscillations in matter”.

Author

Denton, Peter B. and Parke, Stephen J.

Subjects

*PERTURBATION theory, *NEUTRINOS, *OSCILLATIONS, *STANDARD model (Nuclear physics), *SUPERSYMMETRY

Abstract

In this Addendum we rewrite the neutrino mixing angles and mass squared differences in matter given in our original paper, [1], in a notation that is more conventiona for the reader. Replacing the usual neutrino mixing angles and mass squared differences in the expressions for the vacuum oscillation probabilities with these matter mixing angles and mass squared differences gives an excellent approximation to the oscillation probabilities in matter. Comparisons for T2K & T2HK, NOvA, T2HKK and DUNE are also given for neutrinos and anti-neutrinos, disappearance and appearance channels, and for both normal and inverted orderings. [ABSTRACT FROM AUTHOR]

Published

2018

44. Mu-tau reflection symmetry with a high scale texture-zero.

Author

Nishi, C. C., Sánchez-Vega, B. L., and Silva, G. Souza

Subjects

NEUTRINO mass, SYMMETRY breaking, CP violation, STANDARD model (Nuclear physics), NUCLEAR energy

Abstract

The μτ-reflection symmetric neutrino mass matrix can accommodate all known neutrino mixing angles, with maximal atmospheric angle fixed, and predicts all the unknown CP phases of the lepton sector but is unable to predict the absolute neutrino mass scale. Here we present a highly predictive scenario where μτ-reflection is combined with a discrete abelian symmetry to enforce a texture-zero in the mass matrix of the heavy right-handed neutrinos that generate the light neutrino masses. Such a restriction reduces the free parameters of the low energy theory to zero and the absolute neutrino mass scale is restricted to few discrete regions, three in the few meV range and one extending up to around 30 meV. The heavy neutrino sector is dependent only on two free parameters which are further restricted to small regions from the requirement of successful leptogenesis. Mass degenerate heavy neutrinos are possible in one case but there is no resonant enhancement of the CP asymmetry. [ABSTRACT FROM AUTHOR]

Published

2018

45. Heavy neutral fermions at the high-luminosity LHC.

Author

Helo, Juan Carlos, Hirsch, Martin, and Wang, Zeren Simon

Subjects

FERMIONS, LARGE Hadron Collider, STANDARD model (Nuclear physics), SUPERSYMMETRY, NEUTRINO mass

Abstract

Long-lived light particles (LLLPs) appear in many extensions of the standard model. LLLPs are usually motivated by the observed small neutrino masses, by dark matter or both. Typical examples for fermionic LLLPs (a.k.a. heavy neutral fermions, HNFs) are sterile neutrinos or the lightest neutralino in R-parity violating supersymmetry. The high luminosity LHC is expected to deliver up to 3/ab of data. Searches for LLLPs in dedicated experiments at the LHC could then probe the parameter space of LLLP models with unprecedented sensitivity. Here, we compare the prospects of several recent experimental proposals, FASER, CODEX-b and MATHUSLA, to search for HNFs and discuss their relative merits.s [ABSTRACT FROM AUTHOR]

Published

2018

46. Neutrino discovery limit of Dark Matter direct detection experiments in the presence of non-standard interactions.

Author

Gonzalez-Garcia, M. C., Maltoni, Michele, Perez-Gonzalez, Yuber F., and Zukanovich Funchal, Renata

Subjects

DARK matter, NEUTRINO scattering, WEAKLY interacting massive particles, STANDARD model (Nuclear physics), QUANTITATIVE research

Abstract

The detection of coherent neutrino-nucleus scattering by the COHERENT collaboration has set on quantitative grounds the existence of an irreducible neutrino background in direct detection searches of Weakly Interacting Massive Dark Matter candidates. This background leads to an ultimate discovery limit for these experiments: a minimum Dark Matter interaction cross section below which events produced by the coherent neutrino scattering will mimic the Dark Matter signal, the so-called neutrino floor. In this work we study the modification of such neutrino floor induced by non-standard neutrino interactions within their presently allowed values by the global analysis of oscillation and COHERENT data. By using the full likelihood information of such global analysis we consistently account for the correlated effects of non-standard neutrino interactions both in the neutrino propagation in matter and in its interaction in the detector. We quantify their impact on the neutrino floor for five future experiments: DARWIN (Xe), ARGO (Ar), Super-CDMS HV (Ge and Si) and CRESST phase III (CaWO4). Quantitatively, we find that non-standard neutrino interactions allowed at the 3σ level can result in an increase of the neutrino floor of up to a factor ~ 5 with respect to the Standard Model expectations and impact the expected sensitivities of the ARGO, CRESST phase III and DARWIN experiments. [ABSTRACT FROM AUTHOR]

Published

2018

47. DUNE sensitivities to the mixing between sterile and tau neutrinos.

Author

Coloma, Pilar, Forero, David V., and Parke, Stephen J.

Subjects

TAU leptonic neutrino, ELECTROWEAK interactions, STANDARD model (Nuclear physics), NEUTRINO oscillation, RADIOACTIVE decay

Abstract

Light sterile neutrinos can be probed in a number of ways, including electroweak decays, cosmology and neutrino oscillation experiments. At long-baseline experiments, the neutral-current data is directly sensitive to the presence of light sterile neutrinos: once the active neutrinos have oscillated into a sterile state, a depletion in the neutral-current data sample is expected since they do not interact with the Z boson. This channel offers a direct avenue to probe the mixing between a sterile neutrino and the tau neutrino, which is currently only weakly constrained by current data from SuperK, IceCube and NOvA, however, these constrains will continue to improve as more data is collected by these experiments. In this work, we study the potential of the DUNE experiment to constrain the mixing angle which parametrizes this mixing, θ34, through the observation of neutral-current events at the far detector. We find that DUNE will be able to improve significantly over current constraints thanks to its large statistics and excellent discrimination between neutral- and charged-current events. [ABSTRACT FROM AUTHOR]

Published

2018

48. Flavor gauge models below the Fermi scale.

Author

Babu, K., Friedland, A., Machado, P., and Mocioiu, I.

Subjects

FLAVOR in particle physics, GAUGE field theory, STANDARD model (Nuclear physics), FERMI energy, QUARKS

Abstract

The mass and weak interaction eigenstates for the quarks of the third generation are very well aligned, an empirical fact for which the Standard Model offers no explanation. We explore the possibility that this alignment is due to an additional gauge symmetry in the third generation. Specifically, we construct and analyze an explicit, renormalizable model with a gauge boson, X, corresponding to the B − L symmetry of the third family. Having a relatively light (in the MeV to multi-GeV range), flavor-nonuniversal gauge boson results in a variety of constraints from different sources. By systematically analyzing 20 different constraints, we identify the most sensitive probes: kaon, B , D and Upsilon decays, $$ D-{\overline{D}}^0 $$ mixing, atomic parity violation, and neutrino scattering and oscillations. For the new gauge coupling g in the range (10−10) the model is shown to be consistent with the data. Possible ways of testing the model in b physics, top and Z decays, direct collider production and neutrino oscillation experiments, where one can observe nonstandard matter effects, are outlined. The choice of leptons to carry the new force is ambiguous, resulting in additional phenomenological implications, such as non-universality in semileptonic bottom decays. The proposed framework provides interesting connections between neutrino oscillations, flavor and collider physics. [ABSTRACT FROM AUTHOR]

Published

2017

49. Generalized ℤ × ℤ in scaling neutrino Majorana mass matrix and baryogenesis via flavored leptogenesis.

Author

Sinha, Roopam, Samanta, Rome, and Ghosal, Ambar

Subjects

NEUTRINO astrophysics, ORIGANUM, FLAVOR in particle physics, RADIOACTIVE decay, STANDARD model (Nuclear physics)

Abstract

We investigate the consequences of a generalized ℤ × ℤ symmetry on a scaling neutrino Majorana mass matrix. It enables us to determine definite analytical relations between the mixing angles θ and θ , maximal CP violation for the Dirac type and vanishing for the Majorana type. Beside the other testable predictions on the low energy neutrino parameters such as ββ decay matrix element | M | and the light neutrino masses m , the model also has intriguing consequences from the perspective of leptogenesis. With the assumption that the required CP violation for leptogenesis is created by the decay of lightest ( N ) of the heavy Majorana neutrinos, only τ -flavored leptogenesis scenario is found to be allowed in this model. For a normal (inverted) ordering of light neutrino masses, θ is found be less (greater) than its maximal value, for the final baryon asymmetry Y to be in the observed range. Besides, an upper and a lower bound on the mass of N have also been estimated. Effect of the heavier neutrinos N on final Y has been worked out subsequently. The predictions of this model will be tested in the experiments such as nEXO, LEGEND, GERDA-II, T2K, NO νA, DUNE etc. [ABSTRACT FROM AUTHOR]

Published

2017

50. Impact of Beyond the Standard Model physics in the detection of the Cosmic Neutrino Background.

Author

Arteaga, Martín, Bertuzzo, Enrico, Perez-Gonzalez, Yuber, and Funchal, Renata

Subjects

STANDARD model (Nuclear physics), COSMIC neutrino background, TRITIUM, CHIRALITY of nuclear particles, MAJORANA fermions

Abstract

We discuss the effect of Beyond the Standard Model charged current interactions on the detection of the Cosmic Neutrino Background by neutrino capture on tritium in a PTOLEMY-like detector. We show that the total capture rate can be substantially modified for Dirac neutrinos if scalar or tensor right-chiral currents, with strength consistent with current experimental bounds, are at play. We find that the total capture rate for Dirac neutrinos, Γ , can be between 0.3 to 2.2 of what is expected for Dirac neutrinos in the Standard Model, Γ , so that it can be made as large as the rate expected for Majorana neutrinos with only Standard Model interactions. A non-negligible primordial abundance of right-handed neutrinos can only worsen the situation, increasing Γ by 30 to 90%. On the other hand, if a much lower total rate is measured than what is expected for Γ , it may be a sign of new physics. [ABSTRACT FROM AUTHOR]

Published

2017