Planck mass and inflation as consequences of dynamically broken scale invariance

Kubo, Jisuke; Lindner, M.; Schmitz, Kai; Yamada, Masatoshi

doi:10.1103/physrevd.100.015037

Cited by 45 publications

(25 citation statements)

References 138 publications

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“…Here, the cosh (2z I ) factor is a consequence of the relation yy † II ∝ cosh (2z I ), while the cubic power of the RHN mass follows from the two powers of M 1 in Eq. (48) contour lines are also generated by our numerical code, we are able to confirm that they can be reproduced to excellent precision by the analytical expressions in Eqs. (58) and (68).…”

Section: All Plots Insupporting

confidence: 68%

“…In recent years, it has been applied as a tool for BSM model building in a variety of scenarios, ranging from neutrino physics over dark matter to inflation (see, e.g., Refs. [34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49][50]).…”

Section: The Majorana-neutrino Optionmentioning

confidence: 99%

“…This dependence is a direct consequence of the neutrino-option constraint in Eq. (48), which can also be written as…”

Section: All Plots Inmentioning

confidence: 99%

See 2 more Smart Citations

Type I seesaw mechanism as the common origin of neutrino mass, baryon asymmetry, and the electroweak scale

et al. 2019

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The type-I seesaw represents one of the most popular extensions of the Standard Model. Previous studies of this model have mostly focused on its ability to explain neutrino oscillations as well as on the generation of the baryon asymmetry via leptogenesis. Recently, it has been pointed out that the type-I seesaw can also account for the origin of the electroweak scale due to heavy-neutrino threshold corrections to the Higgs potential. In this paper, we show for the first time that all of these features of the type-I seesaw are compatible with each other. Integrating out a set of heavy Majorana neutrinos results in small masses for the Standard Model neutrinos; baryogenesis is accomplished by resonant leptogenesis; and the Higgs mass is entirely induced by heavy-neutrino one-loop diagrams, provided that the tree-level Higgs potential satisfies scale-invariant boundary conditions in the ultraviolet. The viable parameter space is characterized by a heavy-neutrino mass scale roughly in the range 10 6.5···7.0 GeV and a mass splitting among the nearly degenerate heavy-neutrino states up to a few TeV. Our findings have interesting implications for high-energy flavor models and low-energy neutrino observables. We conclude that the type-I seesaw sector might be the root cause behind the masses and cosmological abundances of all known particles. This statement might even extend to dark matter in the presence of a keV-scale sterile neutrino.

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Section: All Plots Insupporting

confidence: 68%

Section: The Majorana-neutrino Optionmentioning

confidence: 99%

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Type I seesaw mechanism as the common origin of neutrino mass, baryon asymmetry, and the electroweak scale

et al. 2019

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“…The "quasi" of "quasi-conformal" is important. It reminds us that the Einstein-Hilbert term and other Weyl-breaking parameters can be present in the Lagrangian, generated, for example, through dimensional transmutation and various quantum effects [3,6,[15][16][17][18][19][20][21][22][23]. Note that an exactly Weyl invariant model would not be physically different from a Weyl-breaking one; indeed, any exactly conformal model can be written as a non-conformal one by fixing a gauge for Weyl symmetry and, conversely, any model of gravity coupled to an arbitrary matter sector can always be made exactly Weyl invariant 4 .…”

Section: Introductionmentioning

confidence: 98%

Quasi-conformal models and the early universe

Salvio

2019

Eur. Phys. J. C

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Extensions of the Standard Model and general relativity featuring a UV fixed point can leave observable implications at accessible energies. Although mass parameters such as the Planck scale can appear through dimensional transmutation, all fundamental dimension-4 operators can (at least approximately) respect Weyl invariance at finite energy. An example is the Weyl-squared term, whose consistency and observational consequences are studied. This quasi-conformal scenario emerges from the UV complete quadratic gravity and is a possible framework for inflation. We find two realizations. In the first one the inflaton is a fundamental scalar with a quasiconformal non-minimal coupling to the Ricci scalar. In this case the field excursion must not exceed the Planck mass by far. An example discussed in detail is hilltop inflation. In the second realization the inflaton is a pseudo-Goldstone boson (natural inflation). In this case we show how to obtain an elegant UV completion within an asymptotically free QCD-like theory, in which the inflaton is a composite scalar due to new strong dynamics. We also show how efficient reheating can occur. Unlike the natural inflation based on Einstein gravity, the tensor-to-scalar ratio is well below the current bound set by Planck. In both realizations mentioned above, the basic inflationary formulae are computed analytically and, therefore, these possibilities can be used as simple benchmark models.---

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“…1(b). This somewhat surprising behavior is due to the asymptotics (32). The latter, in turn, are traced back to the sign of the dilaton kinetic term in eq.…”

Section: The Case δ =mentioning

confidence: 92%

Dilaton-assisted generation of the Fermi scale from the Planck scale

Shkerin

2019

Phys. Rev. D

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In scale-invariant theories of gravity the Planck mass M P , which appears due to spontaneous symmetry breaking, can be the only scale at the classical level. It was argued that the second scale can be generated by a quantum nonperturbative gravitational effect. The new scale, associated with the Higgs vacuum expectation value, can be orders of magnitude below M P , leading to the hierarchy between the Fermi and the Planck scales. We study a theory in which the non-perturbative effect is sensitive both to the physics at energy scales as high as M P and to the low-energy, Standard Model physics. This makes it possible to constrain the mechanism from experiment. We find that the crucial ingredients of the mechanism are non-minimal coupling of the scalar fields to gravity, the approximate Weyl invariance at high energies, and the metastability of the low-energy vacuum.

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Planck mass and inflation as consequences of dynamically broken scale invariance

Cited by 45 publications

References 138 publications

Type I seesaw mechanism as the common origin of neutrino mass, baryon asymmetry, and the electroweak scale

Type I seesaw mechanism as the common origin of neutrino mass, baryon asymmetry, and the electroweak scale

Quasi-conformal models and the early universe

Dilaton-assisted generation of the Fermi scale from the Planck scale

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