Small instantons and the strong 
CP
 problem in composite Higgs models

Abstract We study electroweak baryogenesis in the SO(6)/SO(5) composite Higgs model with the third generation quarks being embedded in the 20′ representation of SO(6). The scalar sector contains one Higgs doublet and one real singlet, and their potential is given by the Coleman-Weinberg potential evaluated from the form factors of the lightest vector and fermion resonances. We show that the resonance masses at $$ \mathcal{O}\left(1\sim 10\kern0.5em \mathrm{TeV}\right) $$ O 1 ∼ 10 TeV can generate a potential that triggers the strong first-order electroweak phase transition (SFOEWPT). The CP violating phase arising from the dimension-6 operator in the top sector is sufficient to yield the observed baryon asymmetry of the universe. The SFOEWPT parameter space is detectable at the future space-based detectors.

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A composite Higgs with a heavy composite axion

Journal of High Energy Physics ◽

10.1007/jhep12(2020)094 ◽

2020 ◽

Vol 2020 (12) ◽

Author(s):

Tony Gherghetta ◽

Minh D. Nguyen

Keyword(s):

Cp Violation ◽

Gauge Group ◽

Scalar Fields ◽

Higgs Model ◽

Global Symmetry ◽

Color Group ◽

High Scale ◽

Axion Mass ◽

Composite Higgs ◽

The Standard Model

Abstract We consider the strong dynamics associated with a composite Higgs model that simultaneously produces dynamical axions and solves the strong CP problem. The strong dynamics arises from a new Sp or SU(4) hypercolor gauge group containing QCD colored hyperfermions that confines at a high scale. The hypercolor global symmetry is weakly gauged by the Standard Model electroweak gauge group and an enlarged color group, SU(N + 3) × SU(N)′. When hyperfermion condensates form, they not only lead to an SU(5)/SO(5) composite Higgs model but also spontaneously break the enlarged color group to SU(3)c× SU(N)D. At lower energies, the SU(N)D group confines, producing two dynamical axions that eliminates all CP violation. Furthermore, small instantons from the SU(N)′ group can enhance the axion mass, giving rise to TeV scale axion masses that can be detected at collider experiments. Our model provides a way to unify the composite Higgs with dynamical axions, without introducing new elementary scalar fields, while also extending the range of axion masses that addresses the strong CP problem.

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A more natural composite Higgs model

Journal of High Energy Physics ◽

10.1007/jhep10(2020)175 ◽

2020 ◽

Vol 2020 (10) ◽

Author(s):

Hsin-Chia Cheng ◽

Yi Chung

Keyword(s):

Standard Model ◽

Higgs Model ◽

Quadratic Term ◽

Beyond The Standard Model ◽

Higgs Potential ◽

Little Higgs ◽

Composite Higgs ◽

Partial Compositeness ◽

Quartic Term ◽

Natural Composite

Abstract Composite Higgs models provide an attractive solution to the hierarchy problem. However, many realistic models suffer from tuning problems in the Higgs potential. There are often large contributions from the UV dynamics of the composite resonances to the Higgs potential, and tuning between the quadratic term and the quartic term is required to separate the electroweak breaking scale and the compositeness scale. We consider a composite Higgs model based on the SU(6)/Sp(6) coset, where an enhanced symmetry on the fermion resonances can minimize the Higgs quadratic term. Moreover, a Higgs quartic term from the collective symmetry breaking of the little Higgs mechanism can be realized by the partial compositeness couplings between elementary Standard Model fermions and the composite operators, without introducing new elementary fields beyond the Standard Model and the composite sector. The model contains two Higgs doublets, as well as several additional pseudo-Nambu-Goldstone bosons. To avoid tuning, the extra Higgs bosons are expected to be relatively light and may be probed in the future LHC runs. The deviations of the Higgs couplings and the weak gauge boson couplings also provide important tests as they are expected to be close to the current limits in this model.

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Phase transitions from the fifth dimension

Journal of High Energy Physics ◽

10.1007/jhep02(2021)051 ◽

2021 ◽

Vol 2021 (2) ◽

Cited By ~ 1

Author(s):

Kaustubh Agashe ◽

Peizhi Du ◽

Majid Ekhterachian ◽

Soubhik Kumar ◽

Raman Sundrum

Keyword(s):

Bubble Dynamics ◽

Effective Field ◽

Bubble Nucleation ◽

Thin Wall ◽

Black Brane ◽

Composite Higgs ◽

Fifth Dimension ◽

Two Phases ◽

Holographic Description ◽

The Impact

Abstract We study the cosmological transition of 5D warped compactifications, from the high-temperature black-brane phase to the low-temperature Randall-Sundrum I phase. The transition proceeds via percolation of bubbles of IR-brane nucleating from the black-brane horizon. The violent bubble dynamics can be a powerful source of observable stochastic gravitational waves. While bubble nucleation is non-perturbative in 5D gravity, it is amenable to semiclassical treatment in terms of a “bounce” configuration interpolating between the two phases. We demonstrate how such a bounce configuration can be smooth enough to maintain 5D effective field theory control, and how a simple ansatz for it places a rigorous lower-bound on the transition rate in the thin-wall regime, and gives plausible estimates more generally. When applied to the Hierarchy Problem, the minimal Goldberger-Wise stabilization of the warped throat leads to a slow transition with significant supercooling. We demonstrate that a simple generalization of the Goldberger-Wise potential modifies the IR-brane dynamics so that the transition completes more promptly. Supercooling determines the dilution of any (dark) matter abundances generated before the transition, potentially at odds with data, while the prompter transition resolves such tensions. We discuss the impact of the different possibilities on the strength of the gravitational wave signals. Via AdS/CFT duality the warped transition gives a theoretically tractable holographic description of the 4D Composite Higgs (de)confinement transition. Our generalization of the Goldberger-Wise mechanism is dual to, and concretely models, our earlier proposal in which the composite dynamics is governed by separate UV and IR RG fixed points. The smooth 5D bounce configuration we introduce complements the 4D dilaton/radion dominance derivation presented in our earlier work.

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Vector-like bottom quarks in composite Higgs models

Journal of High Energy Physics ◽

10.1007/jhep03(2014)037 ◽

2014 ◽

Vol 2014 (3) ◽

Cited By ~ 24

Author(s):

M. Gillioz ◽

R. Gröber ◽

A. Kapuvari ◽

M. Mühlleitner

Keyword(s):

Bottom Quarks ◽

Composite Higgs

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LIGHT COMPOSITE HIGGS: LCH @ LHC

International Journal of Modern Physics A ◽

10.1142/s0217751x05029162 ◽

2005 ◽

Vol 20 (27) ◽

pp. 6133-6148 ◽

Cited By ~ 18

Author(s):

FRANCESCO SANNINO

Keyword(s):

Gauge Group ◽

Higgs Mass ◽

Cold Dark Matter ◽

Precision Measurements ◽

Chiral Phase ◽

Symmetric Representation ◽

Composite Higgs ◽

Higher Dimensional ◽

The One ◽

Intrinsic Scale

Here I summarize some of the salient features of technicolor theories with technifermions in higher dimensional representations of the technicolor gauge group. The expected phase diagram as function of number of flavors and colors for the two index (anti)symmetric representation of the gauge group is reviewed. After having constructed the simplest walking technicolor theory one can show that it is not at odds with the precision measurements. The simplest theory also requires, for consistency, a fourth family of heavy leptons. The latter may result in an interesting signature at LHC. In the case of a fourth family of leptons with ordinary lepton hypercharge the new heavy neutrino can be a natural candidate of cold dark matter. New theories will also be proposed in which the critical number of flavors needed to enter the conformal window is higher than in the one with fermions in the two-index symmetric representation, but lower than in the walking technicolor theories with fermions only in the fundamental representation of the gauge group. Due to the near conformal/chiral phase transition the composite Higgs is very light compared to the intrinsic scale of the technicolor theory. For the two technicolor theory the composite Higgs mass is predicted not to exceed 150 GeV.

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