Your search keyword '"De Angelis, Mariaveronica"' showing total 5 results

1. Metric f(R) gravity with dynamical dark energy as a scenario for the Hubble tension.

Author

Montani, Giovanni, De Angelis, Mariaveronica, Bombacigno, Flavio, and Carlevaro, Nakia

Subjects

*GAMMA ray bursts, *DARK energy, *HUBBLE constant, *REDSHIFT, *GRAVITY, *SCALAR field theory

Abstract

We introduce a theoretical framework to interpret the Hubble tension, based on the combination of a metric f (R) gravity with a dynamical dark energy contribution. The modified gravity provides the non-minimally coupled scalar field responsible for the proper scaling of the Hubble constant, in order to accommodate for the local SNIa pantheon+ data and Planck measurements. The dynamical dark energy source, which exhibits a phantom divide line separating the low redshift quintessence regime (−1 < w < −1/3) from the phantom contribution (w < −1) in the early Universe, guarantees the absence of tachyonic instabilities at low redshift. The resulting H 0(z) profile rapidly approaches the Planck value, with a plateau behaviour for z ≳ 5. In this scenario, the Hubble tension emerges as a low redshift effect, which can be in principle tested by comparing SNIa predictions with far sources, like QUASARS and gamma ray bursts. [ABSTRACT FROM AUTHOR]

Published

2024

2. WKB Approaches to Restore Time in Quantum Cosmology: Predictions and Shortcomings.

Author

Maniccia, Giulia, De Angelis, Mariaveronica, and Montani, Giovanni

Subjects

*QUANTUM cosmology, *QUANTUM field theory, *SCHRODINGER equation, *DEGREES of freedom, *WKB approximation

Abstract

In this review, we analyse different aspects concerning the possibility to separate a gravity-matter system into a part which lives close to a quasi-classical state and a "small" quantum subset. The considered approaches are all relying on a WKB expansion of the dynamics by an order parameter and the natural arena consists of the Bianchi universe minisuperspace. We first discuss how, limiting the WKB expansion to the first order of approximation, it is possible to recover for the quantum subsystem a Schrödinger equation, as written on the classical gravitational background. Then, after having tested the validity of the approximation scheme for the Bianchi I model, we give some applications for the quantum subsystem in the so-called "corner" configuration of the Bianchi IX model. We individualize the quantum variable in the small one of the two anisotropy degrees of freedom. The most surprising result is the possibility to obtain a non-singular Bianchi IX cosmology when the scenario is extrapolated backwards in time. In this respect, we provide some basic hints on the extension of this result to the generic cosmological solution. In the last part of the review, we consider the same scheme to the next order of approximation identifying the quantum subset as made of matter variables only. This way, we are considering the very fundamental problem of non-unitary morphology of the quantum gravity corrections to quantum field theory discussing some proposed reformulations. Instead of constructing the time dependence via that one of the classical gravitational variables on the label time as in previous works, we analyse a recent proposal to construct time by fixing a reference frame. This scheme can be reached both introducing the so-called "kinematical action", as well as by the well-known Kuchar–Torre formulation. In both cases, the Schrödinger equation, amended for quantum gravity corrections, has the same morphology and we provide a cosmological implementation of the model, to elucidate its possible predictions. [ABSTRACT FROM AUTHOR]

Published

2022

3. Modified Gravity in the Presence of Matter Creation: Scenario for the Late Universe.

Author

Montani, Giovanni, Carlevaro, Nakia, and De Angelis, Mariaveronica

Subjects

*HUBBLE constant, *GRAVITATIONAL fields, *ENERGY density, *GRAVITY, UNIVERSE

Abstract

We consider a dynamic scenario for characterizing the late Universe evolution, aiming to mitigate the Hubble tension. Specifically, we consider a metric f (R) gravity in the Jordan frame which is implemented to the dynamics of a flat isotropic Universe. This cosmological model incorporates a matter creation process, due to the time variation of the cosmological gravitational field. We model particle creation by representing the isotropic Universe (specifically, a given fiducial volume) as an open thermodynamic system. The resulting dynamical model involves four unknowns: the Hubble parameter, the non-minimally coupled scalar field, its potential, and the energy density of the matter component. We impose suitable conditions to derive a closed system for these functions of the redshift. In this model, the vacuum energy density of the present Universe is determined by the scalar field potential, in line with the modified gravity scenario. Hence, we construct a viable model, determining the form of the f (R) theory a posteriori and appropriately constraining the phenomenological parameters of the matter creation process to eliminate tachyon modes. Finally, by analyzing the allowed parameter space, we demonstrate that the Planck evolution of the Hubble parameter can be reconciled with the late Universe dynamics, thus alleviating the Hubble tension. [ABSTRACT FROM AUTHOR]

Published

2024

4. Quantum dynamics of the isotropic universe in metric f(R) gravity.

Author

De Angelis, Mariaveronica, Figurato, Laria, and Montani, Giovanni

Subjects

*QUANTUM theory, *SCALAR field theory, *WAVE packets, *GRAVITY, *COSMOLOGICAL constant, *PHASE space, *INFLATIONARY universe, UNIVERSE

Abstract

We analyze the canonical quantum dynamics of the isotropic universe, as emerging from the Hamiltonian formulation of a metric f(R) gravity, viewed in the Jordan frame. The canonical method of quantization is performed by solving the Hamiltonian constraint before quantizing and adopting like a relational time the nonminimally coupled scalar field emerging in the Jordan frame. The resulting Schrödinger evolution is then investigated both in the vacuum and in the presence of a massless scalar field, though as the kinetic component of an inflaton. We show that, in vacuum, the morphology of localized wave packets is that of a nonspreading profile up to the cosmological singularity. When the external scalar field is included into the dynamics, we see that the wave packets acquire the surprising feature of increasing localization of the universe volume, as it expands. This result suggests that, in the metric f(R) formulation of gravity, a spontaneous mechanism arises for the Universe classicalization. Actually, when the phase space of the scalar field is fully explored, such an increasing localization in the Universe volume is valid up to a given value of the time, i.e., of the nonminimally coupled mode after which the wave packets spread again. We conclude our analysis by inferring that before this critical transition age is reached, the inflationary phase could take place, here modeled via a cosmological constant. This point of view provides an interesting scenario for the transition from a Planckian Universe to a classical de-Sitter phase, which in the f(R) gravity appears more natural than in the Einsteinian picture. [ABSTRACT FROM AUTHOR]

Published

2021

5. Dynamics of quantum anisotropies in a Taub universe in the WKB approximation.

Author

De Angelis, Mariaveronica and Montani, Giovanni

Subjects

*WKB approximation, *QUANTUM theory, *SCALAR field theory, *COSMOLOGICAL constant, *PHYSICAL cosmology, *SCHWARZSCHILD black holes, *CASIMIR effect, UNIVERSE

Abstract

We analyze the dynamics of a Taub cosmological model in the presence of a massless minimally coupled scalar field and a cosmological constant, in the limit when both the universe volume and the scalar field live in a quasiclassical approximation. In other words, we study the dynamics of a quantum small anisotropy evolving on a de Sitter background and in the presence of a kinetic term of the inflaton field. We demonstrate that the quantum anisotropy exponentially decays during the universe expansion, approaching a finite and small value. This result suggests that the quantum isotropization of the universe during a de Sitter phase is much weaker than the corresponding classical evolution, favoring the survival of certain degree of anisotropy to the de Sitter phase. Finally we analyze the case when also the scalar field is considered as quantum variable, by showing how its variance naturally spreads because of no potential term significantly affects its dynamics. This behavior results to be different from the anisotropy which is subjected to the potential coming out from the spatial curvature. [ABSTRACT FROM AUTHOR]

Published

2020