The graviton Compton mass as dark energy

Matos, Tonatiuh; -Parrilla, L. L.

doi:10.31349/revmexfis.67.040703

Rev. Mex. Fís.

2021

DOI: 10.31349/revmexfis.67.040703

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The graviton Compton mass as dark energy

Tonatiuh Matos¹,

L. L. -Parrilla²

Abstract: One of the greatest challenges of science is to understand the current accelerated expansion of the Universe. In this work we show that by considering the quantum nature of the gravitational field, its wavelength can be associated to an effective Compton mass. We propose that this mass can be interpreted as dark energy, with a Compton wavelength given by the size of the observable Universe, implying that the dark energy varies depending on this size. If we do so, we find that: 1.- Even without any free constan… Show more

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2024

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Cited by 3 publications

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Cosmology on a gravitational wave background

Matos,

Escamilla,

Hernández-Marquez

et al. 2024

Monthly Notices of the Royal Astronomical Society

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It is a fact that the universe lives on a gravitational wave background (GWB), which is extra space-time energy that is not contained in Einstein’s field equations. In a previous work, this energy is treated as a property of space-time and not as a source. With this in mind, a new model was developed that incorporates this energy to explain the current accelerated expansion of the universe where the GWB was incorporated by extending Einstein’s equations to $R_{\mu \nu }-\frac{1}{2}Rg_{\mu \nu }+\frac{2\pi ^2}{{\lambda }^2}g_{\mu \nu }= \kappa ^2 T_{\mu \nu }$, where λ is the Compton wavelength of the cosmological scale graviton. In the present work we show that this extended form agrees very well with the observations of cosmic chronometers, baryon acoustic oscillations and Pantheon SN type Ia, reproducing the observational data with a Δχ2 = 3.26 in favor of the current model compared to the ΛCDM. The favored values by these observations are Ω0m = 0.311 ± 0.065, H0 = 68.3 ± 1.4 km s−1 Mpc−1, Ω0k = 0.001 ± 0.011. We also find excellent agreement of this model with the cosmic microwave background and the mass power spectrum. We conclude that this model is an excellent alternative to explain the accelerated expansion of the universe without incorporating the cosmological constant or any type of extra matter.

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Cosmology on a gravitational wave background

Matos,

Escamilla,

Hernández-Marquez

et al. 2024

Monthly Notices of the Royal Astronomical Society

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Background gravitational waves as signature of the adiabatic expansion of a black body that represents the dark universe

Cruz,

Amaro de Faria Jr.

2024

Can. J. Phys.

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We propose a toy model of a spherical universe made up of an exotic dark gas with temperature $T$ in thermal equilibrium with a black-body in adiabatic expansion. Each particle of this exotic gas mimics a kind of particle of dark energy represented by the vacuum energy, being quantized into virtual particles with extremely small masses that form such gas representng the own tissue of the expanding space-time governed by a negative pressure whose origin is the equation of state (EOS) of vacuum, i.e., $p=-\rho$, where $\rho$ is the vacuum energy density. So, each vacuum particle occupies a tiny area of space so-called Planck area $L_p^{2}$, which represents the minimum area of the whole space-time given by the spherical surface with area $4\pi R_H^2$, where $R_H$ is the Hubble radius. We realize that such spherical surface is the surface of the black-body for representing the dark universe as if it were the surface of an expanding balloon. Thus, we are able to derive the law of universal gravitation, thus leading us to understand the cosmological anti-gravity. We estimate the very small order of magnitude of the cosmological constant and the acceleration of expansion of the dark sphere. In this toy model, as the dark universe can be thought of as a large black body, when we obtain its power and frequency of emission of radiation, we find very low values. We conclude that such radiation and frequency of the black body made up of dark energy is a background gravitational wave with very low frequency in the order of $10^{-17}$Hz due to the slight stretching of the fabric of space-time.

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Cosmic gravitational background waves in the scenario of a deformed relativity with an invariant minimum speed

Cruz,

Amaro de Faria

2024

Int. J. Mod. Phys. A

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We show the need of the emergence of an invariant minimum speed in the space–time. So, we propose a deformed special relativity with two limits of speed so-called Symmetrical Special Relativity (SSR). It presents a universal minimum speed V that plays the role of a preferred reference frame [Formula: see text] associated with vacuum. This new paradigm of space–time allows us to understand the origin of the cosmological constant [Formula: see text] starting from first principles given by a new kinematic invariance at low energies, which leads us to build a space–time metric with the presence of a minimum speed, so that such metric is equivalent to a de Sitter metric. In order to do that, we use a model of spherical universe with Hubble radius [Formula: see text] filled by a low vacuum energy density [Formula: see text] that governs the accelerated expansion of the universe with negative pressure shown by the equation of state (EOS) of vacuum given by SSR-theory ([Formula: see text]). Thus, we realize that such spherical universe made up of dark energy works like a black body with adiabatic expansion thermalized with a kind of dark gas that plays the role of the dark energy. From this model of virtual particles of dark gas that fills the sphere with dark energy, we are able to derive the law of universal gravitation, allowing us to understand the cosmological anti-gravity according to the EOS of vacuum in the space–time with a minimum speed. So, we estimate the tiny order of magnitude of the cosmological constant and the acceleration of expansion of the dark sphere. In this model, as the dark universe can be thought of as a black body with Hubble radius, we obtain its power and frequency of emission of radiation for a low temperature. We conclude that such radiation is a gravitational wave with an extremely low frequency and power due to the slight stretching of the fabric of space–time, since [Formula: see text] is very small.

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The graviton Compton mass as dark energy

Cited by 3 publications

References 4 publications

Cosmology on a gravitational wave background

Cosmology on a gravitational wave background

Background gravitational waves as signature of the adiabatic expansion of a black body that represents the dark universe

Cosmic gravitational background waves in the scenario of a deformed relativity with an invariant minimum speed

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