Your search keyword '"VOLKAS, RAYMOND R."' showing total 9 results

1. Lowering the scale of Pati-Salam breaking through seesaw mixing.

Author

Dolan, Matthew J., Dutka, Tomasz P., and Volkas, Raymond R.

Subjects

MESON decay, STANDARD model (Nuclear physics), DEGREES of freedom, NEUTRINO mass, HELICITY of nuclear particles, LEPTONS (Nuclear physics), FERMIONS, MESONS

Abstract

We analyse the experimental limits on the breaking scale of Pati-Salam extensions of the Standard Model. These arise from the experimental limits on rare-meson decay processes mediated at tree-level by the vector leptoquark in the model. This leptoquark ordinarily couples to both left- and right-handed SM fermions and therefore the meson decays do not experience a helicity suppression. We find that the current limits vary from O (80–2500) TeV depending on the choice of matrix structure appearing in the relevant three-generational charged-current interactions. We extensively analyse scenarios where additional fermionic degrees of freedom are introduced, transforming as complete Pati-Salam multiplets. These can lower the scales of Pati-Salam breaking through mass-mixing within the charged-lepton and down-quark sectors, leading to a helicity suppression of the meson decay widths which constrain Pati-Salam breaking. We find four multiplets with varying degrees of viability for this purpose: an SU(2)L/R bidoublet, a pair of SU(4) decuplets and either an SU(2)L or SU(2)R triplet all of which contain heavy exotic versions of the SM charged leptons. We find that the Pati-Salam limits can be as low as O (5–150) TeV with the addition of these four multiplets. We also identify an interesting possible connection between the smallness of the neutrino masses and a helicity suppression of the Pati-Salam limits for three of the four multiplets. [ABSTRACT FROM AUTHOR]

Published

2021

2. Radiative muon mass models and (g − 2)μ.

Author

Baker, Michael J., Cox, Peter, and Volkas, Raymond R.

Subjects

MUONS, HIGGS bosons

Abstract

Recent measurements of the Higgs-muon coupling are directly probing muon mass generation for the first time. We classify minimal models with a one-loop radiative mass mechanism and show that benchmark models are consistent with current experimental results. We find that these models are best probed by measurements of (g − 2)μ, even when taking into account the precision of Higgs measurements expected at future colliders. The current (g − 2)μ anomaly, if confirmed, could therefore be a first hint that the muon mass has a radiative origin. [ABSTRACT FROM AUTHOR]

Published

2021

3. Has the origin of the third-family fermion masses been determined?

Author

Baker, Michael J., Cox, Peter, and Volkas, Raymond R.

Subjects

FERMIONS, STANDARD model (Nuclear physics), ATTOSECOND pulses

Abstract

Precision measurements of the Higgs couplings are, for the first time, directly probing the mechanism of fermion mass generation. The purpose of this work is to determine to what extent these measurements can distinguish between the tree-level mechanism of the Standard Model and the theoretically motivated alternative of radiative mass generation. Focusing on the third-family, we classify the minimal one-loop models and find that they fall into two general classes. By exploring several benchmark models in detail, we demonstrate that a radiative origin for the tau-lepton and bottom-quark masses is consistent with current observations. While future colliders will not be able to rule out a radiative origin, they can probe interesting regions of parameter space. [ABSTRACT FROM AUTHOR]

Published

2021

4. A real triplet-singlet extended Standard Model: dark matter and collider phenomenology.

Author

Bell, Nicole F., Dolan, Matthew J., Friedrich, Leon S., Ramsey-Musolf, Michael J., and Volkas, Raymond R.

Subjects

STANDARD model (Nuclear physics), DARK matter, PHENOMENOLOGY, PHASE transitions, ELECTROWEAK interactions, GRAVITATIONAL waves

Abstract

We examine the collider and dark matter phenomenology of the Standard Model extended by a hypercharge-zero SU(2) triplet scalar and gauge singlet scalar. In particular, we study the scenario where the singlet and triplet are both charged under a single ℤ2 symmetry. We find that such an extension is capable of generating the observed dark matter density, while also modifying the collider phenomenology such that the lower bound on the mass of the triplet is smaller than in minimal triplet scalar extensions to the Standard Model. A high triplet mass is in tension with the parameter space that leads to novel electroweak phase transitions in the early universe. Therefore, the lower triplet masses that are permitted in this extended model are of particular importance for the prospects of successful electroweak baryogenesis and the generation of gravitational waves from early universe phase transitions. [ABSTRACT FROM AUTHOR]

Published

2021

5. Exploding operators for Majorana neutrino masses and beyond.

Author

Gargalionis, John and Volkas, Raymond R.

Abstract

Building UV completions of lepton-number-violating effective operators has proved to be a useful way of studying and classifying models of Majorana neutrino mass. In this paper we describe and implement an algorithm that systematises this model-building procedure. We use the algorithm to generate computational representations of all of the tree-level completions of the operators up to and including mass-dimension 11. Almost all of these correspond to models of radiative neutrino mass. Our work includes operators involving derivatives, updated estimates for the bounds on the new-physics scale associated with each operator, an analysis of various features of the models, and a look at some examples. We find that a number of operators do not admit any completions not also generating lower-dimensional operators or larger contributions to the neutrino mass, ruling them out as playing a dominant role in the neutrino-mass generation. Additionally, we show that there are at most five models containing three or fewer exotic multiplets that predict new physics that must lie below 100 TeV. Accompanying this work we also make available a searchable database containing all of our results and the code used to find the completions. We emphasise that our methods extend beyond the study of neutrino-mass models, and may be useful for generating completions of high-dimensional operators in other effective field theories. Example code: ref. [37]. [ABSTRACT FROM AUTHOR]

Published

2021

6. Two-step electroweak symmetry-breaking: theory meets experiment.

Author

Bell, Nicole F., Dolan, Matthew J., Friedrich, Leon S., Ramsey-Musolf, Michael J., and Volkas, Raymond R.

Subjects

ELECTROWEAK interactions, HIGGS bosons, DARK matter, PHASE transitions

Abstract

We study the phenomenology of a hypercharge-zero SU (2) triplet scalar whose existence is motivated by two-step electroweak symmetry-breaking. We consider both the possibility that the triplets are stable and contribute to the dark matter density, or that they decay via mixing with the standard model Higgs boson. The former is constrained by disappearing charged track searches at the LHC and by dark matter direct detection experiments, while the latter is constrained by existing multilepton collider searches. We find that a two-step electroweak phase transition involving a stable triplet with a negative quadratic term is ruled out by direct detection searches, while an unstable triplet with a mass less than 230 GeV is excluded at 95% confidence level. [ABSTRACT FROM AUTHOR]

Published

2020

7. Radiative neutrino mass model from a mass dimension-11 ∆L = 2 effective operator.

Author

Gargalionis, John, Popa-Mateiu, Iulia, and Volkas, Raymond R.

Abstract

We present the first detailed phenomenological analysis of a radiative Majorana neutrino mass model constructed from opening up a ∆L = 2 mass-dimension-11 effective operator constructed out of standard model fields. While three such operators are generated, only one dominates neutrino mass generation, namely O 47 = L C ¯ L Q C ¯ L Q ¯ Q C HH , where L denotes lepton doublet, Q quark doublet and H Higgs doublet. The under- lying renormalisable theory contains the scalars S 1 ∼ 3 ¯ 1 1 / 3 coupling as a diquark, S 3 ∼ 3 ¯ 3 1 / 3 coupling as a leptoquark, and Φ3 ∼ (3, 3, 2/3), which has no Yukawa couplings but does couple to S1 and S3 in addition to the gauge fields. Neutrino masses and mixings are generated at two-loop order. A feature of this model that is different from many other radiative models is the lack of proportionality to any quark and charged- lepton masses of the neutrino mass matrix. One consequence is that the scale of new physics can be as high as 107 TeV, despite the operator having a high mass dimension. This raises the prospect that ∆L = 2 effective operators at even higher mass dimensions may, when opened up, produce phenomenologically-viable radiative neutrino mass models. The parameter space of the model is explored through benchmark slices that are subject to experimental constraints from charged lepton flavour-violating decays, rare meson de- cays and neutral-meson mixing. The acceptable parameter space can accommodate the anomalies in RK (∗) and the anomalous magnetic moment of the muon. [ABSTRACT FROM AUTHOR]

Published

2020

8. A near-minimal leptoquark model for reconciling flavour anomalies and generating radiative neutrino masses.

Author

Bigaran, Innes, Gargalionis, John, and Volkas, Raymond R.

Subjects

NEUTRINO mass, NEUTRINOS, MUONS, STANDARD deviations, LEPTOQUARKS, QUARKS, PREDICTION models

Abstract

We introduce two scalar leptoquarks, the SU(2)L isosinglet denoted ϕ ∼ (3,1, −1/3) and the isotriplet φ ∼ (3,3, −1/3), to explain observed deviations from the standard model in semi-leptonic B-meson decays. We explore the regions of parameter space in which this model accommodates the persistent tensions in the decay observables RD(∗), RK (∗) , and angular observables in b → sμμ transitions. Additionally, we exploit the role of these exotics in existing models for one-loop neutrino mass generation derived from ∆L = 2 effective operators. Introducing the vector-like quark χ ∼ (3,2, −5/6) necessary for lepton-number violation, we consider the contribution of both leptoquarks to the generation of radiative neutrino mass. We find that constraints permit simultaneously accommodating the flavour anomalies while also explaining the relative smallness of neutrino mass without the need for cancellation between leptoquark contributions. A characteristic prediction of our model is a rate of muon-electron conversion in nuclei fixed by the anoma- lies in b → sμμ and neutrino mass; the COMET and Mu2e experiments will thus test and potentially falsify our scenario. The model also predicts signatures that will be tested at the LHC and Belle II. [ABSTRACT FROM AUTHOR]

Published

2019

9. Electroweak baryogenesis with vector-like leptons and scalar singlets.

Author

Bell, Nicole F., Dolan, Matthew J., Friedrich, Leon S., Ramsey-Musolf, Michael J., and Volkas, Raymond R.

Published

2019