Showing total 102 results

1. Probing exotic charged Higgs decays in the Type-II 2HDM through top rich signal at a future 100 TeV pp collider.

Author

Li, Shuailong, Song, Huayang, and Su, Shufang

Subjects

STANDARD model (Nuclear physics), DECISION trees, HIGGS bosons

Abstract

The exotic decay modes of non-Standard Model Higgs bosons are efficient in probing the hierarchical Two Higgs Doublet Models (2HDM). In particular, the decay mode H±→HW± serves as a powerful channel in searching for charged Higgses. In this paper, we analyze the reach for H±→HW±→ t t ¯ W at a 100 TeV pp collider, and show that it extends the reach of the previously studied ττW final states once above the top threshold. Top tagging technique is used, in combination with a boosted decision tree classifier. At the low tan β region, almost the entire hierarchical Type-II 2HDM parameter space can be probed via the combination of all exotic decay channels. [ABSTRACT FROM AUTHOR]

Published

2020

2. Sliding naturalness: cosmological selection of the weak scale.

Author

D'Agnolo, Raffaele Tito and Teresi, Daniele

Subjects

ELECTROWEAK interactions, STANDARD model (Nuclear physics), PLANCK scale, COSMOLOGICAL constant, INFLATIONARY universe, DARK matter, DISCRETE symmetries

Abstract

We present a cosmological solution to the electroweak hierarchy problem. After discussing general features of cosmological approaches to naturalness, we extend the Standard Model with two light scalars very weakly coupled to the Higgs and present the mechanism, which we recently introduced in a companion paper to explain jointly the electroweak hierarchy and the strong-CP problem. In this work we show that this solution can be decoupled from the strong-CP problem and discuss its possible implementations and phenomenology. The mechanism works with any standard inflationary sector, it does not require weak-scale inflation or a large number of e-folds, and does not introduce ambiguities related to eternal inflation. The cutoff of the theory can be as large as the Planck scale, both for the Cosmological Constant and for the Higgs sector. Reproducing the observed dark matter relic density fixes the couplings of the two new scalars to the Standard Model, offering a target to future axion or fifth force searches. Depending on the specific interaction of the scalars with the Standard Model, the mechanism either yields rich phenomenology at colliders or provides a novel joint solution to the strong-CP problem. We highlight what predictions are common to most realizations of cosmological selection of the weak scale and will allow to test this general framework in the near future. [ABSTRACT FROM AUTHOR]

Published

2022

3. New discovery modes for a light charged Higgs boson at the LHC.

Author

Arhrib, A., Benbrik, R., Krab, M., Manaut, B., Moretti, S., Wang, Yan, and Yan, Qi-Shu

Subjects

HIGGS bosons, LARGE Hadron Collider, STANDARD model (Nuclear physics), PAIR production, QUARK decay

Abstract

At the Large Hadron Collider (LHC), both the ATLAS and CMS Collaborations have been searching for light charged Higgs bosons via top (anti)quark production and decays channels, like pp → t t ¯ with one top (anti)quark decaying into a charged Higgs boson and a b (anti)quark, when the decay is kinematically open (i.e., when m H ± ≲ mt). In this paper, we propose new searches at the LHC involving light charged Higgs bosons via their pair production channels like pp → H±h/A and pp → H+H− in the 2-Higgs Doublet Model (2HDM) Type-I and -X scenarios. By focusing on the case where the heavy H state plays the role of the Standard Model (SM)-like Higgs boson with a mass near 125 GeV, we study the aforementioned Higgs boson pair production channels and investigate their bosonic decays, such as H± → W±h and/or H± → W±A. We demonstrate that for a light charged Higgs boson state, with m H ± ≲ mt, at the LHC, such di-Higgs production and decay channels can give rise to signatures with event rates much larger than those emerging from pp → t t ¯ → t b ¯ H− + c.c. We specifically study h/A → b b ¯ and τ+τ− decays. We, therefore, claim that the discussed combination of new production and decay modes can result in an alternative discovery channel for charged Higgs bosons lighter than the top (anti)quark at the LHC within the above two 2HDM Types. Finally, in order to motivate experimentalists in ATLAS and CMS to search for such signatures, we propose 16 Benchmark Points (BPs) which are compatible with both theoretical and experimental constraints. [ABSTRACT FROM AUTHOR]

Published

2021

4. Global electroweak symmetric vacuum.

Author

Bai, Yang, Lee, Seung J., Son, Minho, and Ye, Fang

Subjects

ELECTROWEAK interactions, HIGGS bosons, STANDARD model (Nuclear physics), SYMMETRY breaking, HIGH temperatures, TUNNEL design & construction, TUNNELS

Abstract

Although the Higgs potential in the Standard Model (SM) contains only a simple electroweak symmetry breaking vacuum in the small field region, additional metastable or global vacua could exist in models beyond the SM. In this paper, we study one intriguing scenario with an additional electroweak symmetric vacuum that could be the global one. For the thermal universe ending at the current metastable vacuum, the electroweak symmetry should stay non-restored at high temperatures. We realize the scenario in a model with Higgs-portal couplings to SM singlet scalars with approximately global O(N) symmetries with a large N. For a large portion of model parameter space, both the quantum and thermal tunneling rates are suppressed such that our current metastable vacuum is long-lived enough. Our scenario predicts order-one changes for the Higgs self-couplings and a large contribution to the signal of the off-shell Higgs invisible decay. It can be partly probed at the LHC Run 3 and well tested at the high luminosity LHC. We also discuss the subcritical (anti-de Sitter) bubbles from the thermal tunneling that could have a large population and interesting cosmological implications. [ABSTRACT FROM AUTHOR]

Published

2021

5. Higgs coupling measurements and the scale of new physics.

Author

Abu-Ajamieh, Fayez, Chang, Spencer, Chen, Miranda, and Luty, Markus A.

Subjects

HIGGS bosons, TOP quarks, SCALING (Social sciences), STANDARD model (Nuclear physics), PHYSICS, DEGREES of freedom

Abstract

A primary goal of present and future colliders is measuring the Higgs couplings to Standard Model (SM) particles. Any observed deviation from the SM predictions for these couplings is a sign of new physics whose energy scale can be bounded from above by requiring tree-level unitarity. In this paper, we extend previous work on unitarity bounds from the Higgs cubic coupling to Higgs couplings to vector bosons and top quarks. We find that HL-LHC measurements of these couplings compatible with current experimental bounds may point to a scale that can be explored at the HL-LHC or a next-generation collider. Our approach is completely model-independent: we assume only that there are no light degrees of freedom below the scale of new physics, and allow arbitrary values for the infinitely many couplings beyond the SM as long as they are in agreement with current measurements. We also extend and clarify the methodology of this analysis, and show that if the scale of new physics is above the TeV scale, then the deviations can be described by the leading higher-dimension gauge invariant operator, as in the SM effective field theory. [ABSTRACT FROM AUTHOR]

Published

2021

6. A natural mechanism for approximate Higgs alignment in the 2HDM.

Author

Draper, Patrick, Ekstedt, Andreas, and Haber, Howard E.

Subjects

TOP quarks, STANDARD model (Nuclear physics), HIGGS bosons, SYMMETRY breaking, SYMMETRY

Abstract

The 2HDM possesses a neutral scalar interaction eigenstate whose tree-level properties coincide with the Standard Model (SM) Higgs boson. In light of the LHC Higgs data which suggests that the observed Higgs boson is SM-like, it follows that the mixing of the SM Higgs interaction eigenstate with the other neutral scalar interaction eigenstates of the 2HDM should be suppressed, corresponding to the so-called Higgs alignment limit. The exact Higgs alignment limit can arise naturally due to a global symmetry of the scalar potential. If this symmetry is softly broken, then the Higgs alignment limit becomes approximate (although still potentially consistent with the current LHC Higgs data). In this paper, we obtain the approximate Higgs alignment suggested by the LHC Higgs data as a consequence of a softly broken global symmetry of the Higgs Lagrangian. However, this can only be accomplished if the Yukawa sector of the theory is extended. We propose an extended 2HDM with vector-like top quark partners, where explicit mass terms in the top sector provide the source of the soft symmetry breaking of a generalized CP symmetry. In this way, we can realize approximate Higgs alignment without a significant fine-tuning of the model parameters. We then explore the implications of the current LHC bounds on vector-like top quark partners for the success of our proposed scenario. [ABSTRACT FROM AUTHOR]

Published

2021

7. Reconstruction and identification of boosted di-τ systems in a search for Higgs boson pairs using 13 TeV proton-proton collision data in ATLAS.

Author

Aad, G., Abbott, B., Abbott, D. C., Abed Abud, A., Abeling, K., Abhayasinghe, D. K., Abidi, S. H., AbouZeid, O. S., Abraham, N. L., Abramowicz, H., Abreu, H., Abulaiti, Y., Acharya, B. S., Achkar, B., Adam, L., Adam Bourdarios, C., Adamczyk, L., Adamek, L., Adelman, J., and Adersberger, M.

Subjects

HIGGS bosons, PROTON-proton interactions, STANDARD model (Nuclear physics), GLUONS, LARGE Hadron Collider, PAIR production

Abstract

In this paper, a new technique for reconstructing and identifying hadronically decaying τ+τ− pairs with a large Lorentz boost, referred to as the di-τ tagger, is developed and used for the first time in the ATLAS experiment at the Large Hadron Collider. A benchmark di-τ tagging selection is employed in the search for resonant Higgs boson pair production, where one Higgs boson decays into a boosted b b ¯ pair and the other into a boosted τ+τ− pair, with two hadronically decaying τ-leptons in the final state. Using 139 fb−1 of proton-proton collision data recorded at a centre-of-mass energy of 13 TeV, the efficiency of the di-τ tagger is determined and the background with quark- or gluon-initiated jets misidentified as di-τ objects is estimated. The search for a heavy, narrow, scalar resonance produced via gluon-gluon fusion and decaying into two Higgs bosons is carried out in the mass range 1–3 TeV using the same dataset. No deviations from the Standard Model predictions are observed, and 95% confidence-level exclusion limits are set on this model. [ABSTRACT FROM AUTHOR]

Published

2020

8. Enhancing sensitivities to long-lived particles with high granularity calorimeters at the LHC.

Author

Liu, Jia, Liu, Zhen, Wang, Lian-Tao, and Wang, Xiao-Ping

Subjects

STANDARD model (Nuclear physics), CALORIMETERS, BRANCHING ratios, LARGE Hadron Collider, HIGGS bosons, GLUONS, QUANTUM chromodynamics

Abstract

The search for long-lived particles (LLP) is an exciting physics opportunity in the upcoming runs of the Large Hadron Collider. In this paper, we focus on a new search strategy of using the High Granularity Calorimeter (HGCAL), part of the upgrade of the CMS detector, in such searches. In particular, we demonstrate that the high granularity of the calorimeter allows us to see "shower tracks" in the calorimeter, and can play a crucial role in identifying the signal and suppressing the background. We study the potential reach of the HGCAL using a signal model in which the Standard Model Higgs boson decays into a pair of LLPs, h → XX. After carefully estimating the Standard Model QCD and the misreconstructed fake-track backgrounds, we give the projected reach for both an existing vector boson fusion trigger and a novel displaced-track-based trigger. Our results show that the best reach for the Higgs decay branching ratio, BR(h → XX), in the vector boson fusion channel is about O (10−4) with lifetime cτX ∼ 0.1–1 meters, while for the gluon gluon fusion channel it is about O (10−5–10−6) for similar lifetimes. For longer lifetime cτX ∼ 103 meters, our search could probe BR(h → XX) down to a few ×10−4(10−2) in the gluon gluon fusion (vector boson fusion) channels, respectively. In comparison with these previous searches, our new search shows enhanced sensitivity in complementary regions of the LLP parameter space. We also comment on many improvements can be implemented to further improve our proposed search. [ABSTRACT FROM AUTHOR]

Published

2020

9. Multi-photon production in the Type-I 2HDM.

Author

Arhrib, A., Benbrik, R., Moretti, S., Rouchad, A., Yan, Q. -S., and Xianhui Zhang

Subjects

HIGGS bosons, LARGE Hadron Collider, STANDARD model (Nuclear physics), CONSTRAINTS (Physics), MONTE Carlo method

Abstract

This paper presents a study of a possible contribution to a Higgs boson signal in the hh→γγγγ channel due to H→hh decays, in the framework of the CP-conserving 2-Higgs Doublet Model Type-I (2HDM-I), where the heavier of the two CP-even Higgs bosons defined herein, H, is the SM-like Higgs state observed with a mass of 125 GeV at the Large Hadron Collider (LHC). We perform a broad scan of the 2HDM-I parameter space, in presence of both up-to-date theoretical and experimental constraints, in order to extract the interesting regions yielding such a signal. Then, after validating our numerical framework against public experimental analyses carried out at the LHC, we proceed to assess its scope in constraining and/or extracting the gg→H→hh→γγγγ signal in presence of a sophisticated Monte Carlo (MC) simulation. We find that, over a substantial region of the 2HDM-I parameter space presently un-accessible, the LHC will be able to establish such a potential signature in the next 2--3 years. [ABSTRACT FROM AUTHOR]

Published

2018

10. Phenomenological comparison of models with extended Higgs sectors.

Author

Mühlleitner, Margarete, Sampaio, Marco, Santos, Rui, and Wittbrodt, Jonas

Subjects

SUPERSYMMETRY, HIGGS bosons, STANDARD model (Nuclear physics), GAUGE bosons, PHENOMENOLOGY

Abstract

Beyond the Standard Model (SM) extensions usually include extended Higgs sectors. Models with singlet or doublet fields are the simplest ones that are compatible with the ρ parameter constraint. The discovery of new non-SM Higgs bosons and the identification of the underlying model requires dedicated Higgs properties analyses. In this paper, we compare several Higgs sectors featuring 3 CP-even neutral Higgs bosons that are also motivated by their simplicity and their ability to solve some of the flaws of the SM. They are: the SM extended by a complex singlet field (CxSM), the singlet extension of the 2-Higgs-Doublet Model (N2HDM), and the Next-to-Minimal Supersymmetric SM extension (NMSSM). In addition, we analyse the CP-violating 2-Higgs-Doublet Model (C2HDM), which provides 3 neutral Higgs bosons with a pseudoscalar admixture. This allows us to compare the effects of singlet and pseudoscalar admixtures. Through dedicated scans of the allowed parameter space of the models, we analyse the phenomenologically viable scenarios from the view point of the SM-like Higgs boson and of the signal rates of the non-SM-like Higgs bosons to be found. In particular, we analyse the effect of singlet/pseudoscalar admixture, and the potential to differentiate these models in the near future. This is supported by a study of couplings sums of the Higgs bosons to massive gauge bosons and to fermions, where we identify features that allow us to distinguish the models, in particular when only part of the Higgs spectrum is discovered. Our results can be taken as guidelines for future LHC data analyses, by the ATLAS and CMS experiments, to identify specific benchmark points aimed at revealing the underlying model. [ABSTRACT FROM AUTHOR]

Published

2017

11. Multi-Higgs doublet models: the Higgs-fermion couplings and their sum rules.

Author

Bento, Miguel P., Haber, Howard E., Romão, J. C., and Silva, João P.

Subjects

HIGGS bosons, FERMIONS, SUM rules (Physics), STANDARD model (Nuclear physics), YUKAWA interactions

Abstract

This is the second of a series of papers that explores the physical parameterization, sum rules and unitarity bounds arising from a non-minimal scalar sector of the Standard Model (SM) that consists of N Higgs doublets. In this paper, we focus on the structure and implication of the Yukawa interactions that couple the N scalar doublets to the SM fermions. We employ the charged Higgs basis, which is defined as the basis of scalar fields such that the neutral scalar field vacuum expectation value resides entirely in one of the N scalar doublet fields, and the charged components of the remaining N − 1 scalar doublet fields are the physical (mass-eigenstate) charged Higgs fields. Based on the structure of the Yukawa Lagrangian of the model (and as a consequence of tree-level unitarity), one may deduce numerous sum rules, several of which have not appeared previously in the literature. These sum rules can be used to uncover intimate relations between the structure of the Higgs-fermion couplings and the scalar/gauge couplings. In particular, we show that the approximate alignment limit, in which the W+W− and ZZ couplings to the observed Higgs boson are approximately SM-like, imposes significant constraints on the Higgs-fermion couplings. [ABSTRACT FROM AUTHOR]

Published

2018

12. Searches for additional Higgs bosons and for vector leptoquarks in ττ final states in proton-proton collisions at s = 13 TeV.

Author

Tumasyan, A., Adam, W., Andrejkovic, J. W., Bergauer, T., Chatterjee, S., Damanakis, K., Dragicevic, M., Escalante Del Valle, A., Hussain, P. S., Jeitler, M., Krammer, N., Lechner, L., Liko, D., Mikulec, I., Paulitsch, P., Pitters, F. M., Schieck, J., Schöfbeck, R., Schwarz, D., and Templ, S.

Subjects

HIGGS bosons, PROTON-proton interactions, LEPTOQUARKS, STANDARD model (Nuclear physics), CONFIDENCE intervals, BOSONS

Abstract

Three searches are presented for signatures of physics beyond the standard model (SM) in ττ final states in proton-proton collisions at the LHC, using a data sample collected with the CMS detector at s = 13 TeV, corresponding to an integrated luminosity of 138 fb−1. Upper limits at 95% confidence level (CL) are set on the products of the branching fraction for the decay into τ leptons and the cross sections for the production of a new boson ϕ, in addition to the H(125) boson, via gluon fusion (ggϕ) or in association with b quarks, ranging from O (10 pb) for a mass of 60 GeV to 0.3 fb for a mass of 3.5 TeV each. The data reveal two excesses for ggϕ production with local p-values equivalent to about three standard deviations at mϕ = 0.1 and 1.2 TeV. In a search for t-channel exchange of a vector leptoquark U1, 95% CL upper limits are set on the dimensionless U1 leptoquark coupling to quarks and τ leptons ranging from 1 for a mass of 1 TeV to 6 for a mass of 5 TeV, depending on the scenario. In the interpretations of the M h 125 and M h , EFT 125 minimal supersymmetric SM benchmark scenarios, additional Higgs bosons with masses below 350 GeV are excluded at 95% CL. [ABSTRACT FROM AUTHOR]

Published

2023

13. Search for Higgs boson decays to a Z boson and a photon in proton-proton collisions at s = 13 TeV.

Author

Tumasyan, A., Adam, W., Andrejkovic, J. W., Bergauer, T., Chatterjee, S., Damanakis, K., Dragicevic, M., Escalante Del Valle, A., Frühwirth, R., Jeitler, M., Krammer, N., Lechner, L., Liko, D., Mikulec, I., Paulitsch, P., Pitters, F. M., Schieck, J., Schöfbeck, R., Schwarz, D., and Templ, S.

Subjects

HIGGS bosons, Z bosons, PROTON-proton interactions, STANDARD model (Nuclear physics), BRANCHING ratios, CONFIDENCE intervals

Abstract

Results are presented from a search for the Higgs boson decay H → Zγ, where Z → ℓ+ℓ− with ℓ = e or μ. The search is performed using a sample of proton-proton (pp) collision data at a center-of-mass energy of 13 TeV, recorded by the CMS experiment at the LHC, corresponding to an integrated luminosity of 138 fb−1. Events are assigned to mutually exclusive categories, which exploit differences in both event topology and kinematics of distinct Higgs production mechanisms to enhance signal sensitivity. The signal strength μ, defined as the product of the cross section and the branching fraction σ pp → H B H → Zγ relative to the standard model prediction, is extracted from a simultaneous fit to the ℓ+ℓ−γ invariant mass distributions in all categories and is measured to be μ = 2.4 ± 0.9 for a Higgs boson mass of 125.38 GeV. The statistical significance of the observed excess of events is 2.7 standard deviations. This measurement corresponds to σ pp → H B H → Zγ = 0.21 ± 0.08 pb. The observed (expected) upper limit at 95% confidence level on μ is 4.1 (1.8), where the expected limit is calculated under the background-only hypothesis. The ratio of branching fractions B H → Zγ / B H → γγ is measured to be 1.5 − 0.6 + 0.7 , which agrees with the standard model prediction of 0.69 ± 0.04 at the 1.5 standard deviation level. [ABSTRACT FROM AUTHOR]

Published

2023

14. Cosmological relaxation through the dark axion portal.

Author

Domcke, Valerie, Schmitz, Kai, and You, Tevong

Subjects

ELECTROWEAK interactions, AXIONS, STANDARD model (Nuclear physics), FERMIONS, PHOTONS, PRODUCTION standards

Abstract

The dark axion portal is a coupling of an axion-like particle to a dark photon kinetically mixed with the visible photon. We show how this portal, when applied to the relaxion, can lead to cosmological relaxation of the weak scale using dark photon production. The key backreaction mechanism involves the Schwinger effect: as long as electroweak symmetry is unbroken, Schwinger production of massless Standard Model fermions, which carry dark millicharges, suppresses the dark photon production. Once the electroweak symmetry is broken, the fermions acquire mass and the suppression is lifted. An enhanced dark photon dissipation then traps the relaxion at a naturally small weak scale. Our model thus provides a novel link between the phenomenological dark axion portal, dark photons, and the hierarchy problem of the Higgs mass. [ABSTRACT FROM AUTHOR]

Published

2022

15. The hidden side of scalar-triplet models with spontaneous CP violation.

Author

Ferreira, P. M., Gonçalves, B. L., and Joaquim, F. R.

Subjects

CP violation, NEUTRINO mass, STANDARD model (Nuclear physics), MASS spectrometry

Abstract

Scalar triplet extensions of the Standard Model provide an interesting playground for the explanation of neutrino mass suppression through the type-II seesaw mechanism. Propelled by the possible connections with leptonic CP violation, we explore under which conditions spontaneous CP violation can arise in models with extra scalar triplets. The minimal model satisfying such conditions requires adding two such triplets to the SM field content. For this model, the scalar mass spectrum in both the CP-conserving and spontaneous CP-violating scenarios is studied. In the former case, a decoupling limit for the new scalars can be achieved, while this is not the case when CP is spontaneously broken. In particular, we show that the existence of two light neutral scalars with masses below a few tenths of GeVs is unavoidable in the CP-violating case. Using matrix theory theorems, we derive upper bounds for the masses of those light scalars and briefly examine whether they can still be experimentally viable. Other interesting features of the scalar mass spectrum are discussed as, e.g., the existence of relations among the charged and neutral scalar masses. [ABSTRACT FROM AUTHOR]

Published

2022

16. Same sign trilepton as signature of charged Higgs in two Higgs doublet model.

Author

Mondal, Tanmoy and Sanyal, Prasenjit

Subjects

HIGGS bosons, STANDARD model (Nuclear physics), FERMIONS

Abstract

We explored the prospect of looking for a fermiophobic charged Higgs (H±) via the same sign trilepton signal at the LHC. A fermiophobic scenario appears in the type-I two Higgs doublet model where the coupling of the H± with the Standard Model fermions is inversely proportional to tan β. Almost all the experimental searches rely on the fermionic production and decay of the charged Higgs. Consequently, the limit on H± for fermiophobic scenarios is non-existent unless tan β is small. We show that for a fermiophobic case, the electroweak production of H± is dominant for most of the parameter space. Subsequent bosonic decay of the charged and neutral Higgses give rise to the same sign trilepton signal. With a thorough phenomenological analysis, we demonstrate that the same sign trilepton signal can be an excellent complementary search to explore the high tan β regions. [ABSTRACT FROM AUTHOR]

Published

2022

17. Searching for BSM physics in Yukawa couplings and flavour symmetries.

Author

Alonso-González, J., de Giorgi, A., Merlo, L., and Pokorski, S.

Subjects

STANDARD model (Nuclear physics), PHYSICS, MASS transfer coefficients, HIGGS bosons, SYMMETRY, FERMIONS, QUARKS

Abstract

In the framework of the Standard Model Effective Field Theory, we compare the lower bounds on the scale of new physics possibly contributing to the f f ¯ h effective couplings, obtained from the measurements of different observables, under the assumption that the Wilson coefficients of the relevant dim 6 operators respect certain flavour structure: either the Minimal Flavour Violation (MFV) ansatz or a flavour symmetry, often invoked to explain the observed pattern of fermion masses and mixings. We perform a global analysis of the bounds following from the limits on the diagonal couplings measured in the Higgs boson production and decays at the LHC experiments. Another set of bounds is obtained from the limits on non-diagonal couplings constrained by the variety of flavour changing neutral current (FCNC) and radiative decay processes. With the present precision of the LHC data, the FCNC data give stronger bounds on the scale of new physics than the collider data (obviously, for the MFV ansatz only collider data are relevant): once the Wilson coefficients respect some flavour structure, the obtained bounds are in the TeV range. In the quark case, these limits are compatible with a few percent deviations from the SM Yukawa couplings and only mildly more stringent than those obtained from the available collider data. For leptons, instead, the FCNC bounds are stronger and then a signal in the near future collider data would mean the violation of the flavour symmetry or indicate the presence of additional beyond the Standard Model contributions, affecting the flavour observables, that leads to cancellations. [ABSTRACT FROM AUTHOR]

Published

2022

18. Search for heavy resonances decaying to a pair of Lorentz-boosted Higgs bosons in final states with leptons and a bottom quark pair at s= 13 TeV.

Author

Tumasyan, A., Adam, W., Andrejkovic, J. W., Bergauer, T., Chatterjee, S., Damanakis, K., Dragicevic, M., Escalante Del Valle, A., Frühwirth, R., Jeitler, M., Krammer, N., Lechner, L., Liko, D., Mikulec, I., Paulitsch, P., Pitters, F. M., Schieck, J., Schöfbeck, R., Schwarz, D., and Templ, S.

Subjects

HIGGS bosons, STANDARD model (Nuclear physics), PROTON-proton interactions, RESONANCE, QUARKS, QUARK decay

Abstract

A search for new heavy resonances decaying to a pair of Higgs bosons (HH) in proton-proton collisions at a center-of-mass energy of 13 TeV is presented. Data were collected with the CMS detector at the LHC in 2016–2018, corresponding to an integrated luminosity of 138 fb−1. Resonances with a mass between 0.8 and 4.5 TeV are considered using events in which one Higgs boson decays into a bottom quark pair and the other into final states with either one or two charged leptons. Specifically, the single-lepton decay channel HH → b b ¯ WW ∗ → b b ¯ ℓ v q q ¯ ′ and the dilepton decay channels HH → b b ¯ WW ∗ → b b ¯ ℓ v ℓ v and HH → b b ¯ ττ → b b ¯ ℓ vv ℓ vv are examined, where ℓ in the final state corresponds to an electron or muon. The signal is extracted using a two-dimensional maximum likelihood fit of the H → b b ¯ jet mass and HH invariant mass distributions. No significant excess above the standard model expectation is observed in data. Model-independent exclusion limits are placed on the product of the cross section and branching fraction for narrow spin-0 and spin-2 massive bosons decaying to HH. The results are also interpreted in the context of radion and bulk graviton production in models with a warped extra spatial dimension. The results provide the most stringent limits to date for X → HH signatures with final-state leptons and at some masses provide the most sensitive limits of all X → HH searches. [ABSTRACT FROM AUTHOR]

Published

2022

19. Loop induced single top partner production and decay at the LHC.

Author

Kim, Jeong Han and Lewis, Ian M.

Subjects

LARGE Hadron Collider, SUPERSYMMETRY, HIGGS bosons, PARTICLE physics, STANDARD model (Nuclear physics), PARTICLES (Nuclear physics), PROTON-proton interactions

Abstract

Most searches for top partners, T, are concerned with top partner pair production. However, as these bounds become increasingly stringent, the LHC energy will saturate and single top partner production will become more important. In this paper we study the novel signature of the top partner produced in association with the SM top, pp→Tt¯+tT¯, in a model where the Standard Model (SM) is extended by a vector-like SU(2)L singlet fermion top partner and a real, SM gauge singlet scalar, S. In this model, pp→Tt¯+tT¯ production is possible through loops mediated by the scalar singlet. We find that, with reasonable coupling strengths, the production rate of this channel can dominate top partner pair production at top partner masses of mT ≳ 1.5 TeV. In addition, this model allows for the exotic decay modes T → tg, T → tγ, and T → tS. In much of the parameter space the loop induced decay T → tg dominates and the top partner is quite long lived. New search strategies are necessary to cover these decay modes. We project the the sensitivity of the high luminosity LHC to pp→Tt¯+tT¯ via a realistic collider study. We find with 3 ab−1, the LHC is sensitive to this process for masses mT ≲ 2 TeV. In addition, we provide appendices detailing the renormalization of this model. [ABSTRACT FROM AUTHOR]

Published

2018

20. The Electro-Weak Phase Transition at Colliders: Discovery Post-Mortem.

Author

Papaefstathiou, Andreas and White, Graham

Subjects

PHASE transitions, FIRST-order phase transitions, GRAVITATIONAL wave detectors, SCALAR field theory, STANDARD model (Nuclear physics)

Abstract

We explore the capabilities of a future proton collider to probe the nature of the electro-weak phase transition, following the hypothetical discovery of a new scalar particle. We focus on the real singlet scalar field extension of the Standard Model, representing the most minimal, and challenging to probe, framework that can enable a strong first-order electro-weak phase transition. By constructing detailed phenomenological methods for measuring the mass and accessible couplings of the new scalar particle, we find that a 100 TeV proton collider has the potential to explore the parameter space of the real singlet model and provide meaningful constraints on the electro-weak phase transition. We empirically find some necessary conditions for the realization of a strong first order electroweak phase transition and conjecture that additional information, including through multi-scalar processes and gravitational wave detectors, are likely needed to gauge the nature of the cosmological electro-weak transition. This study represents the first crucial step towards solving the inverse problem in the context of the electro-weak phase transition. [ABSTRACT FROM AUTHOR]

Published

2022

21. 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

22. Electroweak-Skyrmion as asymmetric dark matter.

Author

Hamada, Yu, Kitano, Ryuichiro, and Kurachi, Masafumi

Subjects

DARK matter, BARYONS, UNIVERSE, STANDARD model (Nuclear physics)

Abstract

We propose a scenario that the Electroweak-Skyrmion, a solitonic object made of the Higgs field and the electroweak gauge fields, is identified as an asymmetric dark matter. In this scenario, the relic abundance of the dark matter is related to the baryon asymmetry of the Universe through a sphaleron-like process. We show that the observed ratio of dark matter abundance to the baryon asymmetry can be explained by this scenario with an appropriate choice of model parameters that is allowed by currently available experimental constraints. [ABSTRACT FROM AUTHOR]

Published

2022

23. Festina-Lente bound on Higgs vacuum structure and inflation.

Author

Lee, Sung Mook, Cheong, Dhong Yeon, Hyun, Sang Chul, Park, Seong Chan, and Seo, Min-Seok

Subjects

INFLATIONARY universe, HIGGS bosons, ELECTROWEAK interactions, HUBBLE constant, PRICE inflation, STANDARD model (Nuclear physics), UNIVERSE

Abstract

The recently suggested Festina-Lente (FL) bound provides a lower bound on the masses of U(1) charged particles in terms of the positive vacuum energy. Since the charged particle masses in the Standard Model (SM) are generated by the Higgs mechanism, the FL bound provides a testbed of consistent Higgs potentials in the current dark energy-dominated universe as well as during inflation. We study the implications of the FL bound on the UV behavior of the Higgs potential for a miniscule vacuum energy, as in the current universe. We also present values of the Hubble parameter and the Higgs vacuum expectation value allowed by the FL bound during inflation, which implies that the Higgs cannot stay at the electroweak scale during this epoch. [ABSTRACT FROM AUTHOR]

Published

2022

24. Off-shell Higgs production at the LHC as a probe of the trilinear Higgs coupling.

Author

Haisch, Ulrich and Koole, Gabriël

Subjects

HIGGS bosons, PROTON-proton interactions, STANDARD model (Nuclear physics), MANUFACTURING processes

Abstract

In the context of the Standard Model effective field theory (SMEFT) we examine the constraints on the trilinear Higgs coupling that originate from off-shell Higgs production in proton-proton collisions. Our calculation of the gg → h* → ZZ → 4ℓ process includes two-loop corrections to gluon-gluon-fusion Higgs production and one-loop corrections to the Higgs propagator and its decay. Employing a matrix-element based kinematic discriminant we determine the reach of LHC Run 3 and the high-luminosity option of the LHC in constraining the relevant SMEFT Wilson coefficients. We present constraints that are not only competitive with but also complementary to the projected indirect limits that one expects to obtain from inclusive measurements of single-Higgs production processes at future LHC runs. [ABSTRACT FROM AUTHOR]

Published

2022

25. Non-decoupling new particles.

Author

Banta, Ian, Cohen, Timothy, Craig, Nathaniel, Lu, Xiaochuan, and Sutherland, Dave

Subjects

ELECTROWEAK interactions, STANDARD model (Nuclear physics), HIGGS bosons, SPACE exploration, MODEL theory

Abstract

We initiate the study of a new class of beyond the Standard Model states that we call "Loryons." They have the defining characteristic of being non-decoupling, in the sense that their physical mass is dominated by a contribution from the vacuum expectation value of the Higgs boson. The stakes are high: the discovery of a Loryon would tell us that electroweak symmetry must be non-linearly realized in the effective field theory of the Standard Model. Loryons have their masses bounded from above by perturbative unitarity considerations and thus define a finite parameter space for exploration. After providing a complete catalog of Loryon representations under mild assumptions, we turn to examining the constraints on the parameter space from Higgs couplings measurements, precision electroweak tests, and direct collider searches. We show that most fermionic candidates are already ruled out (with some notable exceptions), while much of the scalar Loryon parameter space is still wide open for discovery. [ABSTRACT FROM AUTHOR]

Published

2022

26. Flavor-violating Higgs decays and stellar cooling anomalies in axion models.

Author

Badziak, Marcin, Grilli di Cortona, Giovanni, Tabet, Mustafa, and Ziegler, Robert

Subjects

AXIONS, HIGGS bosons, STANDARD model (Nuclear physics), NEUTRON stars, PARTICLES (Nuclear physics), QUANTUM chromodynamics

Abstract

We study a class of DFSZ-like models for the QCD axion that can address observed anomalies in stellar cooling. Stringent constraints from SN1987A and neutron stars are avoided by suppressed couplings to nucleons, while axion couplings to electrons and photons are sizable. All axion couplings depend on few parameters that also control the extended Higgs sector, in particular lepton flavor-violating couplings of the Standard Model-like Higgs boson h. This allows us to correlate axion and Higgs phenomenology, and we find that BR(h → τe) can be as large as the current experimental bound of 0.22%, while BR(h → μμ) can be larger than in the Standard Model by up to 70%. Large parts of the parameter space will be tested by the next generation of axion helioscopes such as the IAXO experiment. [ABSTRACT FROM AUTHOR]

Published

2021

27. Probing extended scalar sectors with precision e+e−→ Zh and Higgs diphoton studies.

Author

Ramsey-Musolf, Michael J., Yu, Jiang-Hao, and Zhou, Jia

Subjects

HIGGS bosons, LARGE Hadron Collider, STANDARD model (Nuclear physics), PARTICLE interactions

Abstract

We compute the one-loop corrections to σ(e+e−→ Zh) arising from representative extended Standard Model scalar sector scenarios. According to the new scalar SU(2)L representations, we consider the inert doublet, real and complex triplet, quintuplet, and septuplet models. With the sub-percent level precision expected for prospective future e+e− collider measurements of σ(e+e−→ Zh), studies of the Higgsstrahlung process will probe extended scalar sector particle spectrum and interactions in a manner complementary to direct searches at the Large Hadron Collider and possible future pp colliders. We also compare with the sensitivity of future Higgs diphoton decay rate measurements. We find that the σ(e+e−→ Zh) and Γ(h → γγ) complementarity is particularly pronounced for the complex triplet model. [ABSTRACT FROM AUTHOR]

Published

2021

28. Phenomenology of a fake Inert Doublet Model.

Author

Anselmi, Damiano, Kannike, Kristjan, Marzo, Carlo, Marzola, Luca, Melis, Aurora, Müürsepp, Kristjan, Piva, Marco, and Raidal, Martti

Subjects

ELECTROWEAK interactions, HIGGS bosons, STANDARD model (Nuclear physics), PHENOMENOLOGY, DEGREES of freedom, PHYSICS

Abstract

We introduce a new way of modeling the physics beyond the Standard Model by considering fake, strictly off-shell degrees of freedom: the fakeons. To demonstrate the approach and exemplify its reach, we re-analyze the phenomenology of the Inert Doublet Model under the assumption that the second doublet is a fakeon. Remarkably, the fake doublet avoids the most stringent Z-pole constraints regardless of the chosen mass scale, thereby allowing for the presence of new effects well below the electroweak scale. Furthermore, the absence of on-shell propagation prevents fakeons from inducing missing energy signatures in collider experiments. The distinguishing features of the model appear at the loop level, where fakeons modify the Higgs boson h → γγ decay width and the Higgs trilinear coupling. The running of Standard Model parameters proceeds as in the usual Inert Doublet Model case. Therefore, the fake doublet can also ensure the stability of the Standard Model vacuum. Our work shows that fakeons are a valid alternative to the usual tools of particle physics model building, with the potential to shape a new paradigm, where the significance of the existing experimental constraints towards new physics must necessarily be reconsidered. [ABSTRACT FROM AUTHOR]

Published

2021

29. Towards a Higgs mass determination in asymptotically safe gravity with a dark portal.

Author

Eichhorn, Astrid, Pauly, Martin, and Ray, Shouryya

Subjects

STANDARD model (Nuclear physics), TOP quarks, HIGGS bosons, QUANTUM gravity, GRAVITONS, GRAVITY

Abstract

There are indications that an asymptotically safe UV completion of the Standard Model with gravity could constrain the Higgs self-coupling, resulting in a prediction of the Higgs mass close to the vacuum stability bound in the Standard Model. The predicted value depends on the top quark mass and comes out somewhat higher than the experimental value if the current central value for the top quark mass is assumed. Beyond the Standard Model, the predicted value also depends on dark fields coupled through a Higgs portal. Here we study the Higgs self-coupling in a toy model of the Standard Model with quantum gravity that we extend by a dark scalar and fermion. Within the approximations used in [1], there is a single free parameter in the asymptotically safe dark sector, as a function of which the predicted (toy model) Higgs mass can be lowered due to mixing effects if the dark sector undergoes spontaneous symmetry breaking. [ABSTRACT FROM AUTHOR]

Published

2021

30. Measuring Higgs boson self-couplings with 2 → 3 VBS processes.

Author

Chen, Junmou, Lu, Chih-Ting, and Wu, Yongcheng

Subjects

STANDARD model (Nuclear physics), HIGGS bosons, HADRON colliders, BOSONS, MUONS

Abstract

We study the measurement of Higgs boson self-couplings through 2 → 3 vector boson scattering (VBS) processes in the framework of Standard Model effective field theory (SMEFT) at both proton and lepton colliders. The SMEFT contribution to the amplitude of the 2 → 3 VBS processes, taking WLWL → WLWLh and WLWL → hhh as examples, exhibits enhancement with the energy A BSM A SM ~ E 2 Λ 2 , which indicates the sensitivity of these processes to the related dimension-six operators in SMEFT. Simulation of the full processes at both hadron and lepton colliders with a variety of collision energies are performed to estimate the allowed region on c6 and c Φ 1 . Especially we find that, with the help of exclusively choosing longitudinal polarizations in the final states and suitable pT cuts, WWh process is as important as the more widely studied triple Higgs production (hhh) in the measurement of Higgs self-couplings. Our analysis indicates that these processes can play important roles in the measurement of Higgs self-couplings at future 100 TeV pp colliders and muon colliders. However, their cross sections are generally tiny at low energy machines, which makes them much more challenging to explore. [ABSTRACT FROM AUTHOR]

Published

2021

31. One-loop corrections to the Higgs boson invisible decay in the dark doublet phase of the N2HDM.

Author

Azevedo, Duarte, Gabriel, Pedro, Mühlleitner, Margarete, Sakurai, Kodai, and Santos, Rui

Subjects

LARGE Hadron Collider, BRANCHING ratios, STANDARD model (Nuclear physics), ELECTROWEAK interactions, HIGGS bosons, DARK matter

Abstract

The Higgs invisible decay width may soon become a powerful tool to probe extensions of the Standard Model with dark matter candidates at the Large Hadron Collider. In this work, we calculate the next-to-leading order (NLO) electroweak corrections to the 125 GeV Higgs decay width into two dark matter particles. The model is the next-to-minimal 2-Higgs-doublet model (N2HDM) in the dark doublet phase, that is, only one doublet and the singlet acquire vacuum expectation values. We show that the present measurement of the Higgs invisible branching ratio, BR(H → invisible < 0.11), does not lead to constraints on the parameter space of the model at leading order. This is due to the very precise measurements of the Higgs couplings but could change in the near future. Furthermore, if NLO corrections are required not to be unphysically large, no limits on the parameter space can be extracted from the NLO results. [ABSTRACT FROM AUTHOR]

Published

2021

32. Searching for pseudo Nambu-Goldstone boson dark matter production in association with top quarks.

Author

Haisch, Ulrich, Polesello, Giacomo, and Schulte, Stefan

Subjects

TOP quarks, NAMBU-Goldstone bosons, DARK matter, STANDARD model (Nuclear physics), LARGE Hadron Collider

Abstract

Pseudo Nambu-Goldstone bosons (pNGBs) are attractive dark matter (DM) candidates, since they couple to the Standard Model (SM) predominantly through derivative interactions. Thereby they naturally evade the strong existing limits inferred from DM direct detection experiments. Working in an effective field theory that includes both derivative and non-derivative DM-SM operators, we perform a detailed phenomenological study of the Large Hadron Collider reach for pNGB DM production in association with top quarks. Drawing on motivated benchmark scenarios as examples, we compare our results to other collider limits as well as the constraints imposed by DM (in) direct detection experiments and the relic abundance. We furthermore explore implications on the viable parameter space of pNGB DM. In particular, we demonstrate that DM direct detection experiments become sensitive to many pNGB DM realisations once loop-induced interactions are taken into account. The search strategies and pNGB DM benchmark models that we discuss can serve as a starting point for dedicated experimental analyses by the ATLAS and the CMS collaborations. [ABSTRACT FROM AUTHOR]

Published

2021

33. Composite Higgs revealed in Higgs pair photo-production at future colliders.

Author

Bharucha, A., Cacciapaglia, G., Deandrea, A., Gaur, N., Harada, D., Mahmoudi, F., and Sridhar, K.

Subjects

HIGGS bosons, STANDARD model (Nuclear physics), PAIR production, STANDARD deviations, FERMIONS, PHYSICS

Abstract

The next generation electron-positron colliders are designed for precision studies of the Standard Model and its extensions, in particular in the Higgs sector. We consider the potential for discovery of composite Higgs models in Higgs pair production through photon collisions. This process is loop-generated, thus it provides access to all Higgs couplings and can show new physics effects in polarized and unpolarized cross-sections starting at relatively low collider energies. It is, therefore, relevant for all electron-positron colliders planned or in preparation. Sizeable deviations from the Standard Model predictions are present in a general class of composite Higgs models, as couplings of one or more Higgs bosons to fermions, or fermionic and scalar resonances, modify the destructive interference present in the Standard Model. In particular, large effects are due to the new quartic coupling of the Higgs to tops and to the presence of a light scalar resonance. [ABSTRACT FROM AUTHOR]

Published

2021

34. 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

35. Enhancement of the double Higgs production via leptoquarks at the LHC.

Author

Da Rold, Leandro, Epele, Manuel, Medina, Anibal, Mileo, Nicolás I., and Szynkman, Alejandro

Subjects

LEPTOQUARKS, HIGGS bosons, STANDARD model (Nuclear physics), TIMEKEEPING, LUMINOSITY

Abstract

Measurements of single Higgs production and its decays are in good agreement with the Standard Model. There is still room for large modifications in double Higgs production at LHC, though these effects may be correlated with large corrections to other observables, in particular single Higgs production. In this work we address the issue of enhancing double Higgs production in the presence of scalar leptoquarks while satisfying all experimental constraints. We show at leading order that including more than one species of leptoquarks, large cubic interactions with the Higgs can lead to sizable enhancement of di-Higgs production cross section at LHC, while at the same time keeping other Higgs observables and precision measurements under control. For masses above 800 GeV these corrections are in general below 30%, whereas in a viable scenario in which one of the leptoquarks can be light, specifically in the mass range 400 − 600 GeV, we show that it is possible to roughly double the SM cross section for di-Higgs production, implying that possible first hints of it may be probed at the high luminosity LHC at L ∼ 2 ab−1. [ABSTRACT FROM AUTHOR]

Published

2021

36. Shedding light on dark matter with recent muon (g − 2) and Higgs exotic decay measurements.

Author

Lu, Chih-Ting, Ramos, Raymundo, and Tsai, Yue-Lin Sming

Subjects

DARK matter, STANDARD model (Nuclear physics), HIGGS bosons, MUONS, PHYSICS

Abstract

Recently, we have witnessed two hints of physics beyond the standard model: a 3.3σ local excess ( M A 0 = 52 GeV) in the search for H0 → A0A0 → b b ¯ μ+μ− and a 4.2σ deviation from the SM prediction in the (g − 2)μ measurement. The first excess was found by the ATLAS collaboration using 139 fb−1 data at s = 13 TeV. The second deviation is a combination of the results from the Brookhaven E821 and the recently reported Fermilab E989 experiment. We attempt to explain these deviations in terms of a renormalizable simplified dark matter model. Inspired by the null signal result from dark matter (DM) direct detection, we interpret the possible new particle, A0, as a pseudoscalar mediator connecting DM and the standard model. On the other hand, a new vector-like muon lepton can explain these two excesses at the same time while contributing to the DM phenomenology. [ABSTRACT FROM AUTHOR]

Published

2021

37. Twin Higgs portal dark matter.

Author

Curtin, David and Gryba, Shayne

Subjects

DARK matter, DISCRETE symmetries, SIGNAL detection, STANDARD model (Nuclear physics)

Abstract

Many minimal models of dark matter (DM) or canonical solutions to the hierarchy problem are either excluded or severely constrained by LHC and direct detection null results. In particular, Higgs Portal Dark Matter (HPDM) features a scalar coupling to the Higgs via a quartic interaction, and obtaining the measured relic density via thermal freeze-out gives definite direct detection predictions which are now almost entirely excluded. The Twin Higgs solves the little hierarchy problem without coloured top partners by introducing a twin sector related to the Standard Model (SM) by a discrete symmetry. We generalize HPDM to arbitrary Twin Higgs models and introduce Twin Higgs Portal Dark Matter (THPDM), which features a DM candidate with an SU(4)-invariant quartic coupling to the Twin Higgs scalar sector. Given the size of quadratic corrections to the DM mass, its most motivated scale is near the mass of the radial mode. In that case, DM annihilation proceeds with the full Twin Higgs portal coupling, while direct detection is suppressed by the pNGB nature of the 125 GeV Higgs. For a standard cosmological history, this results in a predicted direct detection signal for THPDM that is orders of magnitude below that of HPDM with very little dependence on the precise details of the twin sector, evading current bounds but predicting possible signals at next generation experiments. In many Twin Higgs models, twin radiation contributions to ∆Neff are suppressed by an asymmetric reheating mechanism. We study this by extending the νMTH and X MTH models to include THPDM and compute the viable parameter space according to the latest CMB bounds. The injected entropy dilutes the DM abundance as well, resulting in additional suppression of direct detection below the neutrino floor. [ABSTRACT FROM AUTHOR]

Published

2021

38. The electro-weak phase transition at colliders: confronting theoretical uncertainties and complementary channels.

Author

Papaefstathiou, Andreas and White, Graham

Subjects

PHASE transitions, FIRST-order phase transitions, ELECTROWEAK interactions, HIGGS bosons, SCALAR field theory, STANDARD model (Nuclear physics), UNCERTAINTY, PROTON transfer reactions

Abstract

We explore and contrast the capabilities of future colliders to probe the nature of the electro-weak phase transition. We focus on the real singlet scalar field extension of the Standard Model, representing the most minimal, yet most elusive, framework that can enable a strong first-order electro-weak phase transition. By taking into account the theoretical uncertainties and employing the powerful complementarity between gauge and Higgs boson pair channels in the searches for new scalar particles, we find that a 100 TeV proton collider has the potential to confirm or falsify a strong first-order transition. Our results hint towards this occurring relatively early in its lifetime. Furthermore, by extrapolating down to 27 TeV, we find that a lower-energy collider may also probe a large fraction of the parameter space, if not all. Such early discoveries would allow for precise measurements of the new phenomena to be obtained at future colliders and would pave the way to definitively verify whether this is indeed the physical remnant of a scalar field that catalyses a strong first-order transition. [ABSTRACT FROM AUTHOR]

Published

2021

39. Top, Higgs, diboson and electroweak fit to the Standard Model effective field theory.

Author

Ellis, John, Madigan, Maeve, Mimasu, Ken, Sanz, Veronica, and You, Tevong

Subjects

ELECTROWEAK interactions, STANDARD model (Nuclear physics), PARTICLE physics, SFERMION, GLOBAL analysis (Mathematics), LINEAR statistical models

Abstract

The search for effective field theory deformations of the Standard Model (SM) is a major goal of particle physics that can benefit from a global approach in the framework of the Standard Model Effective Field Theory (SMEFT). For the first time, we include LHC data on top production and differential distributions together with Higgs production and decay rates and Simplified Template Cross-Section (STXS) measurements in a global fit, as well as precision electroweak and diboson measurements from LEP and the LHC, in a global analysis with SMEFT operators of dimension 6 included linearly. We present the constraints on the coefficients of these operators, both individually and when marginalised, in flavour-universal and top-specific scenarios, studying the interplay of these datasets and the correlations they induce in the SMEFT. We then explore the constraints that our linear SMEFT analysis imposes on specific ultra-violet completions of the Standard Model, including those with single additional fields and low-mass stop squarks. We also present a model-independent search for deformations of the SM that contribute to between two and five SMEFT operator coefficients. In no case do we find any significant evidence for physics beyond the SM. Our underlying Fitmaker public code provides a framework for future generalisations of our analysis, including a quadratic treatment of dimension-6 operators. [ABSTRACT FROM AUTHOR]

Published

2021

40. Testing aligned CP-violating Higgs sector at future lepton colliders.

Author

Kanemura, Shinya, Kubota, Mitsunori, and Yagyu, Kei

Subjects

YUKAWA interactions, ELECTRIC dipole moments, HIGGS bosons, COUPLING constants, STANDARD model (Nuclear physics), LEPTONS (Nuclear physics), CP violation

Abstract

We discuss the testability of CP-violating phases at future lepton colliders for the scenario which satisfies electric dipole moment data by destructive interferences among several phases. We consider the general but aligned two Higgs doublet model which has the CP-violating phases in the Higgs potential and the Yukawa interaction. The Yukawa interaction terms are aligned to avoid flavor changing neutral currents at tree level. The Higgs potential is also aligned such that the coupling constants of the lightest Higgs boson with the mass of 125 GeV to the Standard Model (SM) particles are the same as those of the SM at tree level. We investigate the azimuthal angle distribution of the hadronic decay of tau leptons arising from production and decay of the extra Higgs bosons, which contains information of the CP-violating phases. From the signal and background simulation, we find that the scenario with finite CP-violating phases can be distinguished from CP conserving one at future lepton colliders like the International Linear Collider. [ABSTRACT FROM AUTHOR]

Published

2021

41. 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

42. Collider searches for scalar singlets across lifetimes.

Author

Fuchs, Elina, Matsedonskyi, Oleksii, Savoray, Inbar, and Schlaffer, Matthias

Subjects

HADRON colliders, STANDARD model (Nuclear physics), SPACE probes, HIGGS bosons

Abstract

Spin-0 singlets arise in well-motivated extensions of the Standard Model. Their lifetime determines the best search strategies at hadron and lepton colliders. To cover a large range of singlet decay lengths, we investigate bounds from Higgs decays into a pair of singlets, considering signatures of invisible decays, displaced and delayed jets, and coupling fits of untagged decays. We examine the generic scalar singlet and the relaxion, and derive a matching as well as qualitative differences between them. For each model, we discuss its natural parameter space and the searches probing it. [ABSTRACT FROM AUTHOR]

Published

2021

43. Probing electroweak phase transition with multi-TeV muon colliders and gravitational waves.

Author

Liu, Wei and Xie, Ke-Pan

Subjects

MUONS, PHASE transitions, HIGGS bosons, STANDARD model (Nuclear physics), GRAVITATIONAL waves, BOSONS

Abstract

We study the complementarity of the proposed multi-TeV muon colliders and the near-future gravitational wave (GW) detectors to the first order electroweak phase transition (FOEWPT), taking the real scalar extended Standard Model as the representative model. A detailed collider simulation shows the FOEWPT parameter space can be greatly probed via the vector boson fusion production of the singlet, and its subsequent decay to the di-Higgs or di-boson channels. Especially, almost all the parameter space yielding detectable GW signals can be probed by the muon colliders. Therefore, if we could detect stochastic GWs in the future, a muon collider could provide a hopeful crosscheck to identify their origin. On the other hand, there is considerable parameter space that escapes GW detections but is within the reach of the muon colliders. The precision measurements of Higgs couplings could also probe the FOEWPT parameter space efficiently. [ABSTRACT FROM AUTHOR]

Published

2021

44. Searching for GeV-scale Majorana Dark Matter: inter spem et metum.

Author

Jueid, Adil, Nasri, Salah, and Soualah, Rachik

Subjects

DARK matter, MAJORANA fermions, STANDARD model (Nuclear physics), PAIR production, LEPTONS (Nuclear physics), HIGGS bosons, NEUTRINOS

Abstract

We suggest a minimal model for GeV-scale Majorana Dark Matter (DM) coupled to the standard model lepton sector via a charged scalar singlet. We show that there is an anti-correlation between the spin-independent DM-Nucleus scattering cross section (σSI) and the DM relic density for parameters values allowed by various theoretical and experimental constraints. Moreover, we find that even when DM couplings are of order unity, σSI is below the current experimental bound but above the neutrino floor. Furthermore, we show that the considered model can be probed at high energy lepton colliders using e.g. the mono-Higgs production and same-sign charged Higgs pair production. [ABSTRACT FROM AUTHOR]

Published

2021

45. Cosmological phase transitions: is effective field theory just a toy?

Author

Postma, Marieke and White, Graham

Subjects

PHASE transitions, STANDARD model (Nuclear physics), TOYS, HIGGS bosons, FRIEDMANN equations

Abstract

To obtain a first order phase transition requires large new physics corrections to the Standard Model (SM) Higgs potential. This implies that the scale of new physics is relatively low, raising the question whether an effective field theory (EFT) description can be used to analyse the phase transition in a (nearly) model-independent way. We show analytically and numerically that first order phase transitions in perturbative extensions of the SM cannot be described by the SM-EFT. The exception are Higgs-singlet extension with tree-level matching; but even in this case the SM-EFT can only capture part of the full parameter space, and if truncated at dim-6 operators, the description is at most qualitative. We also comment on the applicability of EFT techniques to dark sector phase transitions. [ABSTRACT FROM AUTHOR]

Published

2021

46. Is SMEFT enough?

Author

Cohen, Timothy, Craig, Nathaniel, Lu, Xiaochuan, and Sutherland, Dave

Subjects

ELECTROWEAK interactions, NAMBU-Goldstone bosons, STANDARD model (Nuclear physics), HIGGS bosons, SYMMETRY breaking, INDEPENDENT sets, PHYSICS

Abstract

There are two canonical approaches to treating the Standard Model as an Effective Field Theory (EFT): Standard Model EFT (SMEFT), expressed in the electroweak symmetric phase utilizing the Higgs doublet, and Higgs EFT (HEFT), expressed in the broken phase utilizing the physical Higgs boson and an independent set of Goldstone bosons. HEFT encompasses SMEFT, so understanding whether SMEFT is sufficient motivates identifying UV theories that require HEFT as their low energy limit. This distinction is complicated by field redefinitions that obscure the naive differences between the two EFTs. By reformulating the question in a geometric language, we derive concrete criteria that can be used to distinguish SMEFT from HEFT independent of the chosen field basis. We highlight two cases where perturbative new physics must be matched onto HEFT: (i) the new particles derive all of their mass from electroweak symmetry breaking, and (ii) there are additional sources of electroweak symmetry breaking. Additionally, HEFT has a broader practical application: it can provide a more convergent parametrization when new physics lies near the weak scale. The ubiquity of models requiring HEFT suggests that SMEFT is not enough. [ABSTRACT FROM AUTHOR]

Published

2021

47. The emergence of electroweak Skyrmions through Higgs bosons.

Author

Criado, Juan Carlos, Khoze, Valentin V., and Spannowsky, Michael

Subjects

HIGGS bosons, SKYRMIONS, ELECTROWEAK interactions, STANDARD model (Nuclear physics), BARYONS, ACTIVATION energy, FINITE fields

Abstract

Skyrmions are extended field configurations, initially proposed to describe baryons as topological solitons in an effective field theory of mesons. We investigate and confirm the existence of skyrmions within the electroweak sector of the Standard Model and study their properties. We find that the interplay of the electroweak sector with a dynamical Higgs field and the Skyrme term leads to a non-trivial vacuum structure with the skyrmion and perturbative vacuum sectors separated by a finite energy barrier. We identify dimension-8 operators that stabilise the electroweak skyrmion as a spatially localised soliton field configuration with finite size. Such operators are induced generically by a wide class of UV models. To calculate the skyrmion energy and radius we use a neural network method. Electroweak skyrmions are non-topological solitons but are exponentially long lived, and we find that the electroweak skyrmion is a viable dark matter candidate. While the skyrmion production cross section at collider experiments is suppressed, measuring the size of the Skyrme term in multi-Higgs-production processes at high-energy colliders is a promising avenue to probe the existence of electroweak skyrmions. [ABSTRACT FROM AUTHOR]

Published

2021

48. 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

49. Probing the top-Higgs sector with composite Higgs models at present and future hadron colliders.

Author

Bautista, Carlos, de Lima, Leonardo, D'Elia Matheus, Ricardo, Pontón, Eduardo, Fernandes do Prado, Leônidas A., and Savoy-Navarro, Aurore

Subjects

HADRON colliders, STANDARD model (Nuclear physics), BRANCHING ratios, POINT set theory, RESONANCE, FERMIONS

Abstract

We study the production of t t ¯ h and t t ¯ hh at hadron colliders, in the minimal Composite Higgs Models, based on the coset SO(5)/SO(4). We explore the fermionic representations 5 and 14. A detailed phenomenological analysis is performed, covering the energy range of the LHC and its High Luminosity upgrade, as well as that of a future 100 TeV hadron collider. Both resonant and non-resonant production are considered, stressing the interplay and complementary interest of these channels with each other and double Higgs production. We provide sets of representative points with detailed experimental outcomes in terms of modification of the cross sections as well as resonance masses and branching ratios. For non-resonant production, we gauge the relative importance of Yukawa, Higgs trilinear, and contact t t ¯ hh vertices to these processes, and consider the prospect for distinguishing the fermion representations from each other and from the Standard Model. In the production of top partners, we find that the three-body decay channel W+W–t becomes significant in certain regions of parameter space having a degenerate spectrum, and is further enhanced by increasing the top partner's mass. This motivates both higher energy machines as well as the need to go beyond the current analysis performed for the searches for these resonances. [ABSTRACT FROM AUTHOR]

Published

2021

50. The Feynman rules for the SMEFT in the background field gauge.

Author

Corbett, Tyler

Subjects

STANDARD model (Nuclear physics)

Abstract

We present a package for FeynRules which derives the Feynman rules for the Standard Model Effective Field Theory up to dimension-six using the background field method for gauge fixing. The package includes operators which shift the kinetic and mass terms of the Lagrangian up to dimension-eight and including dimension-six squared effects consistently. To the best of the author's knowledge this is the first publicly available package to include dimension-six squared effects consistently. The package is validated in a partner publication by analyzing the Ward Identities at dimension-six and one-loop order. We also extend the partner work in this article by including the dimension-six squared effects further demonstrating the consistency of their implementation. In doing so we find that failure to consistently include field shifts to dimension-six squared causes a breakdown in the Ward identities implying concerns about many calculations in the literature which do not properly incorporate these effects. The FeynRules files, as well as Mathematica notebooks performing the relevant calculations, can be downloaded from the FeynRules website and are included as supplementary material to this publication. [ABSTRACT FROM AUTHOR]

Published

2021