Fine-tuning free paradigm of two-measures theory:k-essence, absence of initial singularity of the curvature, and inflation with graceful exit to the zero cosmological constant state

A recent work proposed that the recent cosmic passage to a cosmic acceleration era is the result of the existence of small anti-gravity sources in each galaxy and clusters of galaxies. In particular, a Swiss-cheese cosmology model, which relativistically integrates the contribution of all these anti-gravity sources on a galactic scale has been constructed assuming the presence of an infrared fixed point for a scale dependent cosmological constant. The derived cosmological expansion provides an explanation for both the fine tuning and the coincidence problem. The present work relaxes the previous assumption on the running of the cosmological constant and allows for a generic scaling around the infrared fixed point. Our analysis reveals that, in order to produce a cosmic evolution consistent with the best ΛCDM model, the IR-running of the cosmological constant is consistent with the presence of an IR-fixed point.

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The possibility of a stable flat dark energy-dominated Swiss-cheese brane-world universe

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887820500759 ◽

2020 ◽

Vol 17 (05) ◽

pp. 2050075

Author(s):

Nasr Ahmed ◽

Kazuharu Bamba ◽

F. Salama

Keyword(s):

Dark Energy ◽

Cosmological Constant ◽

Cosmological Models ◽

Brane World ◽

Fine Tuning ◽

Energy Conditions ◽

Late Time ◽

Swiss Cheese ◽

Black Strings ◽

The Stability

In this paper, we study the possibility of obtaining a stable flat dark energy-dominated universe in a good agreement with observations in the framework of Swiss-cheese brane-world cosmology. Two different brane-world cosmologies with black strings have been introduced for any cosmological constant [Formula: see text] using two empirical forms of the scale factor. In both models, we have performed a fine-tuning between the brane tension and the cosmological constant so that the Equation of state (EoS) parameter [Formula: see text] for the current epoch, where the redshift [Formula: see text]. We then used these fine–tuned values to calculate and plot all parameters and energy conditions. The deceleration–acceleration cosmic transition is allowed in both models, and the jerk parameter [Formula: see text] at late-times. Both solutions predict a future dark energy-dominated universe in which [Formula: see text] with no crossing to the phantom divide line. While the pressure in the first solution is always negative, the second solution predicts a better behavior of cosmic pressure where the pressure is negative only in the late-time accelerating era but positive in the early-time decelerating era. Such a positive-to-negative transition in the evolution of pressure helps to explain the cosmic deceleration–acceleration transition. Since black strings have been proved to be unstable by some authors, this instability can actually reflect doubts on the stability of cosmological models with black strings (Swiss-cheese type brane-worlds cosmological models). For this reason, we have carefully investigated the stability through energy conditions and sound speed. Because of the presence of quadratic energy terms in Swiss-cheese type brane-world cosmology, we have tested the new nonlinear energy conditions in addition to the classical energy conditions. We have also found that a negative tension brane is not allowed in both models of the current work as the energy density will no longer be well defined.

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From inflation to a zero cosmological constant phase without fine-tuning

Physical Review D ◽

10.1103/physrevd.57.7200 ◽

1998 ◽

Vol 57 (12) ◽

pp. 7200-7203 ◽

Cited By ~ 15

Author(s):

E. I. Guendelman ◽

A. B. Kaganovich

Keyword(s):

Cosmological Constant ◽

Fine Tuning

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Supersymmetric quantum field theory (QFT): Introduction

Quantum Field Theory and Critical Phenomena ◽

10.1093/oso/9780198834625.003.0027 ◽

2021 ◽

pp. 656-669

Author(s):

Jean Zinn-Justin

Keyword(s):

Cosmological Constant ◽

Particle Physics ◽

Vector Fields ◽

Hadron Collider ◽

Large Mass ◽

Momentum Tensor ◽

Fine Tuning ◽

Four Dimensions ◽

New Feature ◽

The Masses

Supersymmetry has been proposed, in particular as a principle to solve the so-called fine-tuning problem in particle physics by relating the masses of scalar particles (like Higgs fields) to those of fermions, which can be protected against ‘large’ mass renormalization by chiral symmetry. However, supersymmetry is, at best, an approximate symmetry broken at a scale beyond the reach of a large hadron collider (LHC), because the possible supersymmetric partners of known particles have not been discovered yet (2020) and thus, if they exist, must be much heavier. Exact supersymmetry would also have implied the vanishing of the vacuum energy and thus, of the cosmological constant. The discovery of dark energy has a natural interpretation as resulting from a very small cosmological constant. However, a naive model based on broken supersymmetry would still predict 60 orders of magnitude too large a value compared to 120 orders of magnitude otherwise. Gauging supersymmetry leads naturally to a unification with gravity, because the commutators of supersymmetry currents involve the energy momentum tensor. First, examples of supersymmetric theories involving scalar superfields, simple generalizations of supersymmetric quantum mechanics (QM) are described. The new feature of supersymmetry in higher dimensions is the combination of supersymmetry with spin, since fermions have spins. In four dimensions, theories with chiral scalar fields and vector fields are constructed.

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Revisiting the decoupling effects in the running of the Cosmological Constant

International Journal of Modern Physics A ◽

10.1142/s0217751x18450136 ◽

2018 ◽

Vol 33 (34) ◽

pp. 1845013

Author(s):

Oleg Antipin ◽

Blaženka Melić

Keyword(s):

Cosmological Constant ◽

Higgs Mass ◽

Vacuum Energy ◽

Fine Tuning ◽

Simple Extension ◽

Heavy Particles ◽

Entire Energy Range ◽

The Standard Model ◽

Entire Energy ◽

Mass Dependent

We revisit the decoupling effects associated with heavy particles in the renormalization group running of the vacuum energy in a mass-dependent renormalization scheme. We find the running of the vacuum energy stemming from the Higgs condensate in the entire energy range and show that it behaves as expected from the simple dimensional arguments, meaning that it exhibits the quadratic sensitivity to the mass of the heavy particles in the infrared regime. The consequence of such a running to the fine-tuning problem with the measured value of the Cosmological Constant is analyzed and the constraint on the mass spectrum of a given model is derived. We show that in the Standard Model (SM) this fine-tuning constraint is not satisfied while in the massless theories this constraint formally coincides with the well-known Veltman condition. We also provide a remarkably simple extension of the SM where saturation of this constraint enables us to predict the radiative Higgs mass correctly. Generalization to constant curvature spaces is also given.

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Cosmological constant decaying with CMB temperature

International Journal of Geometric Methods in Modern Physics ◽

10.1142/s0219887819500889 ◽

2019 ◽

Vol 16 (06) ◽

pp. 1950088 ◽

Cited By ~ 1

Author(s):

Tomohide Sonoda

Keyword(s):

Cosmological Constant ◽

Fine Tuning ◽

Field Equations ◽

Microwave Background ◽

Dark Energy Density ◽

Dimension Formula ◽

Large Numbers ◽

The Hierarchical Structure ◽

The Universe ◽

Cmb Temperature

Recent observations of the dark energy density have demonstrated the fine-tuning problem and the challenges faced by theoretical modeling. In this study, we apply the self-similar symmetry (SSS) model, describing the hierarchical structure of the universe based on the Dirac large numbers hypothesis, to Einstein’s cosmological term. We introduce a new similarity dimension, [Formula: see text], in the SSS model. Using the [Formula: see text] SSS model, the cosmological constant [Formula: see text] is simply expressed as a function of the cosmic microwave background (CMB) temperature. The result shows that both the gravitational constant [Formula: see text] and [Formula: see text] are coupled with the CMB temperature, which simplifies the solution of Einstein’s field equations for the variable [Formula: see text]–[Formula: see text] model.

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AN EARLY UNIVERSE MODEL WITH STIFF MATTER AND A COSMOLOGICAL CONSTANT

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194511001346 ◽

2011 ◽

Vol 03 ◽

pp. 254-265 ◽

Cited By ~ 6

Author(s):

G. OLIVEIRA-NETO ◽

G. A. MONERAT ◽

E. V. CORRÊA SILVA ◽

C. NEVES ◽

L. G. FERREIRA FILHO

Keyword(s):

Cosmological Constant ◽

Perfect Fluid ◽

Scale Factor ◽

Initial Singularity ◽

Discrete Energy ◽

Classical Level ◽

Stiff Matter ◽

Expectation Value ◽

Variational Formalism ◽

Friedmann Robertson Walker

In the present work, we study the quantum cosmology description of a Friedmann-Robertson-Walker model in the presence of a stiff matter perfect fluid and a negative cosmological constant. We work in the Schutz's variational formalism and the spatial sections have constant negative curvature. We quantize the model and obtain the appropriate Wheeler-DeWitt equation. In this model the states are bounded therefore we compute the discrete energy spectrum and the corresponding eigenfunctions. In the present work, we consider only the negative eigenvalues and their corresponding eigenfunctions. This choice implies that the energy density of the perfect fluid is negative. A stiff matter perfect fluid with this property produces a model with a bouncing solution, at the classical level, free from an initial singularity. After that, we use the eigenfunctions in order to construct wave packets and evaluate the time-dependent expectation value of the scale factor. We find that it oscillates between maximum and minimum values. Since the expectation value of the scale factor never vanishes, we confirm that this model is free from an initial singularity, also, at the quantum level.

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DARK MATTER AND DARK ENERGY - FACT OR FANTASY?

International Journal of Modern Physics A ◽

10.1142/s0217751x04022554 ◽

2004 ◽

Vol 19 (31) ◽

pp. 5333-5333

Author(s):

PHILIP MANNHEIM

Keyword(s):

Dark Matter ◽

Dark Energy ◽

Cosmological Constant ◽

Particle Physics ◽

Einstein Gravity ◽

Fine Tuning ◽

Accelerating Universe ◽

Conformal Invariant ◽

Invariant Metric ◽

Conformal Theory

We show that the origin of the dark matter and dark energy problems originates in the assumption of standard Einstein gravity that Newton's constant is fundamental. We discuss an alternate, conformal invariant, metric theory of gravity in which Newton's constant is induced dynamically, with the global induced one which is effective for cosmology being altogether weaker than the local induced one needed for the solar system. We find that in the theory dark matter is no longer needed, and that the accelerating universe data can be fitted without fine-tuning using a cosmological constant as large as particle physics suggests. In the conformal theory then it is not the cosmological constant which is quenched but rather the amount of gravity that it produces.

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Cosmological constant, quantum measurement and the problem of time

International Journal of Modern Physics D ◽

10.1142/s0218271815440113 ◽

2015 ◽

Vol 24 (12) ◽

pp. 1544011 ◽

Cited By ~ 1

Author(s):

Shreya Banerjee ◽

Sayantani Bera ◽

Tejinder P. Singh

Keyword(s):

General Relativity ◽

Cosmological Constant ◽

Quantum Measurement ◽

Quantum States ◽

Fine Tuning ◽

Theoretical Physics ◽

Hamiltonian Constraint ◽

Linear Superposition ◽

Problem Of Time ◽

Apparent Violation

Three of the big puzzles of theoretical physics are the following: (i) There is apparently no time evolution in the dynamics of quantum general relativity (QGR), because the allowed quantum states must obey the Hamiltonian constraint. (ii) During a quantum measurement, the state of the quantum system randomly collapses from being in a linear superposition of the eigenstates of the measured observable, to just one of the eigenstates, in apparent violation of the predictions of the deterministic, linear Schrödinger equation. (iii) The observed value of the cosmological constant is exceedingly small, compared to its natural value, creating a serious fine-tuning problem. In this essay, we propose a novel idea to show how the three problems help solve each other.

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On the Higgs-like quintessence for dark energy

Modern Physics Letters A ◽

10.1142/s021773231450117x ◽

2014 ◽

Vol 29 (22) ◽

pp. 1450117 ◽

Cited By ~ 6

Author(s):

Sergei V. Ketov ◽

Natsuki Watanabe

Keyword(s):

Dark Energy ◽

Cosmological Constant ◽

Scalar Curvature ◽

Scalar Potential ◽

Fine Tuning ◽

Standard Description ◽

Quintessence Model

We propose a dynamical (quintessence) model of dark energy in the current Universe with a renormalizable (Higgs-like) scalar potential. We prove the viability of our model (after fine-tuning) for the certain range of the average scalar curvature values, and study the cosmological signatures distinguishing our model from the standard description of dark energy in terms of a cosmological constant.

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