The Higgs boson and cosmology

I will discuss how the Higgs field of the Standard Model may have played an important role in cosmology, leading to the homogeneity, isotropy and flatness of the Universe; producing the quantum fluctuations that seed structure formation; triggering the radiation-dominated era of the hot Big Bang; and contributing to the processes of baryogenesis and dark matter production.

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Outstanding questions: physics beyond the Standard Model

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2011.0452 ◽

2012 ◽

Vol 370 (1961) ◽

pp. 818-830 ◽

Cited By ~ 17

Author(s):

John Ellis

Keyword(s):

Dark Matter ◽

Higgs Boson ◽

Large Hadron Collider ◽

Standard Model ◽

Particle Physics ◽

Hadron Collider ◽

Beyond The Standard Model ◽

The Standard Model ◽

The Difference ◽

The Universe

The Standard Model of particle physics agrees very well with experiment, but many important questions remain unanswered, among them are the following. What is the origin of particle masses and are they due to a Higgs boson? How does one understand the number of species of matter particles and how do they mix? What is the origin of the difference between matter and antimatter, and is it related to the origin of the matter in the Universe? What is the nature of the astrophysical dark matter? How does one unify the fundamental interactions? How does one quantize gravity? In this article, I introduce these questions and discuss how they may be addressed by experiments at the Large Hadron Collider, with particular attention to the search for the Higgs boson and supersymmetry.

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Relativistic Cosmology with an Introduction to Inflation

Universe ◽

10.3390/universe7080276 ◽

2021 ◽

Vol 7 (8) ◽

pp. 276

Author(s):

Muhammad Zahid Mughal ◽

Iftikhar Ahmad ◽

Juan Luis García Guirao

Keyword(s):

Standard Model ◽

Early Universe ◽

Large Scale ◽

Initial Conditions ◽

Big Bang ◽

Relativistic Cosmology ◽

The Standard Model ◽

Big Bang Model ◽

The Big Bang ◽

The Universe

In this review article, the study of the development of relativistic cosmology and the introduction of inflation in it as an exponentially expanding early phase of the universe is carried out. We study the properties of the standard cosmological model developed in the framework of relativistic cosmology and the geometric structure of spacetime connected coherently with it. The geometric properties of space and spacetime ingrained into the standard model of cosmology are investigated in addition. The big bang model of the beginning of the universe is based on the standard model which succumbed to failure in explaining the flatness and the large-scale homogeneity of the universe as demonstrated by observational evidence. These cosmological problems were resolved by introducing a brief acceleratedly expanding phase in the very early universe known as inflation. The cosmic inflation by setting the initial conditions of the standard big bang model resolves these problems of the theory. We discuss how the inflationary paradigm solves these problems by proposing the fast expansion period in the early universe. Further inflation and dark energy in fR modified gravity are also reviewed.

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The gravitational condensate of the higgs field

10.31219/osf.io/fdqbm ◽

2019 ◽

Author(s):

Vitaly Kuyukov

Keyword(s):

Higgs Boson ◽

Standard Model ◽

Higgs Field ◽

Higgs Bosons ◽

Grand Unification ◽

Gravitational Potential Energy ◽

Mass Hierarchy ◽

The Standard Model ◽

Cell Condensation ◽

The Difference

This paper analyses a method of producing the Higgs mass via the gravitational field. This approach has become very popular in recent years, as the consideration of other forces do not help in solving the problem of mass hierarchy. Not understand the difference between scales of the standard model and Grand unification theory. Here, we present a heuristic mechanism which eliminated this difference. The idea is that the density of the condensate of the Higgs is increased so that it is necessary to take into account self gravitational potential energy of the Higgs boson. The result is as follows. The mass of the Higgs is directly proportional to the cell density of the Higgs bosons. Or else the mass of the Higgs is inversely proportional to the cell volume, which is the Higgs boson in the condensate. The most interesting dimension of this cell condensation is equal to the scale of Grand unification. This formula naturally combines the scale of the standard model and Grand unification through gravitational condensation.

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Constraining extended scalar sectors at the LHC and beyond

Modern Physics Letters A ◽

10.1142/s0217732318300070 ◽

2018 ◽

Vol 33 (10n11) ◽

pp. 1830007 ◽

Cited By ~ 40

Author(s):

Agnieszka Ilnicka ◽

Tania Robens ◽

Tim Stefaniak

Keyword(s):

Dark Matter ◽

Higgs Boson ◽

Standard Model ◽

Parameter Space ◽

Beyond The Standard Model ◽

The Standard Model ◽

Doublet Model ◽

Inert Doublet Model ◽

Scalar Sector ◽

Scalar Singlet

We give a brief overview of beyond the Standard Model (BSM) theories with an extended scalar sector and their phenomenological status in the light of recent experimental results. We discuss the relevant theoretical and experimental constraints, and show their impact on the allowed parameter space of two specific models: the real scalar singlet extension of the Standard Model (SM) and the Inert Doublet Model. We emphasize the importance of the LHC measurements, both the direct searches for additional scalar bosons, as well as the precise measurements of properties of the Higgs boson of mass 125 GeV. We show the complementarity of these measurements to electroweak and dark matter observables.

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Probes for 4th Generation Constituents of Dark Atoms in Higgs Boson Studies at the LHC

Advances in High Energy Physics ◽

10.1155/2014/406458 ◽

2014 ◽

Vol 2014 ◽

pp. 1-7 ◽

Cited By ~ 4

Author(s):

M. Yu. Khlopov ◽

R. M. Shibaev

Keyword(s):

Dark Matter ◽

Higgs Boson ◽

Big Bang ◽

Decay Rates ◽

Neutral Atoms ◽

Big Bang Nucleosynthesis ◽

Charged Species ◽

The Difference ◽

The Universe ◽

Direct Dark Matter

The nonbaryonic dark matter of the Universe can consist of new stable charged species, bound in heavy neutral “atoms” by ordinary Coulomb interaction. StableU-(anti-U)quarks of 4th generation, bound in stable colorless(U- U- U-)clusters, are captured by the primordial helium, produced in Big Bang Nucleosynthesis, thus forming neutral “atoms” of O-helium (OHe), a specific nuclear interacting dark matter that can provide solution for the puzzles of direct dark matter searches. However, the existence of the 4th generation quarks and leptons should influence the production and decay rates of Higgs boson and is ruled out by the experimental results of the Higgs boson searches at the LHC, if the Higgs boson coupling to 4th generation fermions is not suppressed. Here, we argue that the difference between the three known quark-lepton families and the 4th family can naturally lead to suppression of this coupling, relating the accelerator test for such a composite dark matter scenario to the detailed study of the production and modes of decay of the 125.5 GeV boson, discovered at the LHC.

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Conformal complex singlet extension of the Standard Model: scenario for dark matter and a second Higgs boson

Journal of High Energy Physics ◽

10.1007/jhep08(2016)065 ◽

2016 ◽

Vol 2016 (8) ◽

Cited By ~ 13

Author(s):

Zhi-Wei Wang ◽

T. G. Steele ◽

T. Hanif ◽

R. B. Mann

Keyword(s):

Dark Matter ◽

Higgs Boson ◽

Standard Model ◽

The Standard Model

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THE HIGGS PORTAL AND AN UNIFIED MODEL FOR DARK ENERGY AND DARK MATTER

International Journal of Modern Physics A ◽

10.1142/s0217751x08042675 ◽

2008 ◽

Vol 23 (30) ◽

pp. 4817-4827 ◽

Cited By ~ 45

Author(s):

O. BERTOLAMI ◽

R. ROSENFELD

Keyword(s):

Dark Matter ◽

Dark Energy ◽

Higgs Boson ◽

Higgs Field ◽

Vacuum Expectation ◽

Classical Field ◽

Dark Matter Candidate ◽

Hidden Sector ◽

Quintessence Field ◽

The Universe

We examine a scenario where the Higgs boson is coupled to an additional Standard Model singlet scalar field from a hidden sector. We show that, in the case where this field is very light and has already relaxed to its nonzero vacuum expectation value, one gets a very stringent limit on the mixing angle between the hidden sector scalar and the Higgs field from fifth force experiments. However, this limit does not imply in a small coupling due to the large difference of vacuum expectation values. In the case that the hidden sector scalar is identified with the quintessence field, responsible for the recent acceleration of the universe, the most natural potential describing the interaction is disfavored since it results in a time-variation of the Fermi scale. We show that an ad hoc modification of the potential describing the Higgs interaction with the quintessence field may result in an unified picture of dark matter and dark energy, where dark energy is the zero-mode classical field rolling the usual quintessence potential and the dark matter candidate is the quantum excitation (particle) of the field, which is produced in the universe due to its coupling to the Higgs boson. This coupling also generates a mass for the new particle that, contrary to usual quintessence models, does not have to be small, since it does not affect the evolution of classical field. In this scenario, a feasible dark matter density can be, under conditions, obtained.

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ELECTROWEAK UNIFICATION OF QUARKS AND LEPTONS IN A GAUGE GROUP SUC(3) × SU(4) × UX(1)

International Journal of Modern Physics A ◽

10.1142/s0217751x12501175 ◽

2012 ◽

Vol 27 (21) ◽

pp. 1250117 ◽

Cited By ~ 2

Author(s):

FAYYAZUDDIN

Keyword(s):

Dark Matter ◽

Standard Model ◽

Gauge Group ◽

Lower Limit ◽

Z Boson ◽

Early Stage ◽

Mass Scale ◽

The Standard Model ◽

Vector Bosons ◽

The Universe

A model for electroweak unification of quarks and leptons, in a gauge group SUC(3) × SU(4) × UX(1) is constructed. The model requires, three generations of quarks and leptons which are replicas (mirror) of the standard quarks and leptons. The gauge group SU(4) × UX(1) is broken in such a way so as to reproduce standard model and to generate heavy masses for the vector bosons [Formula: see text], the leptoquarks and mirror fermions. It is shown lower limit on mass scale of mirror fermions is [Formula: see text], E- being the lightest mirror fermion coupled to Z boson. As the universe expands, the heavy matter is decoupled at an early stage of expansion and may be a source of dark matter. Leptoquarks in the model connect the standard model and mirror fermions. Baryon genesis in our universe implies antibaryon genesis in mirror universe.

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Alternative cosmological theories

The Oxford Handbook of the History of Modern Cosmology ◽

10.1093/oxfordhb/9780198817666.013.4 ◽

2019 ◽

pp. 119-161

Author(s):

Helge Kragh

Keyword(s):

Standard Model ◽

Cosmic Time ◽

Big Bang ◽

Field Equations ◽

Static Universe ◽

The Standard Model ◽

Scientific Nature ◽

Big Bang Model ◽

The Universe ◽

Alternative Theories

Since about 1970 the broadly accepted theory of the universe has been the standard hot big-bang model. However, there is and has always been alternative theories which challenge one or more features of the standard model or, more radically, question the scientific nature of cosmology. Is the universe governed by Einstein’s field equations? Is it really in a state of expansion? Did it begin with a big bang? The chapter discusses various alternative or heterodox theories in the period from about 1930 to 1980, among them the idea of a static universe and the conception that our universe evolves cyclically in infinite cosmic time. While some of these theories have been abandoned long ago, others still live on and are cultivated by a minority of cosmologists and other scientists.

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Baryogenesis and dark matter in U(1) extensions

Modern Physics Letters A ◽

10.1142/s0217732317400053 ◽

2017 ◽

Vol 32 (15) ◽

pp. 1740005 ◽

Cited By ~ 3

Author(s):

Wan-Zhe Feng ◽

Pran Nath

Keyword(s):

Dark Matter ◽

Standard Model ◽

Lepton Number ◽

Current Data ◽

Neutrino Masses ◽

Neutrino Experiment ◽

The Standard Model ◽

Reactor Neutrino ◽

The Universe ◽

Neutrino Masses And Mixings

A brief review is given of some recent works where baryogenesis and dark matter have a common origin within the U(1) extensions of the Standard Model (SM) and of the minimal supersymmetric Standard Model (MSSM). The models considered generate the desired baryon asymmetry and the dark matter to baryon ratio. In one model, all of the fundamental interactions do not violate lepton number, and the total [Formula: see text] in the Universe vanishes. In addition, one may also generate a normal hierarchy of neutrino masses and mixings in conformity with the current data. Specifically, one can accommodate [Formula: see text] consistent with the data from Daya Bay reactor neutrino experiment.

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