Your search keyword '"Vera, Raül"' showing total 3 results

1. New characterization of Robertson–Walker geometries involving a single timelike curve.

Author

Mars, Marc and Vera, Raül

Subjects

*GENERAL relativity (Physics), *SPACETIME, *GEOMETRY, *CURVATURE, *GEODESICS

Abstract

Our aim in this paper is two-fold. We establish a novel geometric characterization of the Robertson–Walker (RW) spacetime and, along the process, we find a canonical form of the RW metric associated to an arbitrary timelike curve and an arbitrary space frame. A known characterization establishes that a spacetime foliated by constant curvature leaves whose orthogonal flow (the cosmological flow) is geodesic, shear-free, and with constant expansion on each leaf, is RW. We generalize this characterization by relaxing the condition on the expansion. We show it suffices to demand that the spatial gradient and Laplacian of the cosmological expansion on a single arbitrary timelike curve vanish. In General Relativity these local conditions are equivalent to demanding that the energy flux measured by the cosmological flow, as well as its divergence, are zero on a single arbitrary timelike curve. The proof allows us to construct canonically adapted coordinates to the arbitrary curve, thus well-fitted to an observer with an arbitrary motion with respect to the cosmological flow. [ABSTRACT FROM AUTHOR]

Published

2024

2. Review on the matching conditions for the tidal problem: towards the application to more general contexts.

Author

Aranguren, Eneko and Vera, Raül

Subjects

*PERTURBATION theory, *NEUTRON stars, *SUPERFLUIDITY, *PHASE transitions, *GENERAL relativity (Physics), *MATCHING theory

Abstract

The tidal problem is used to obtain the tidal deformability (or Love number) of stars. The semi-analytical study is usually treated in perturbation theory as a first order perturbation problem over a spherically symmetric background configuration consisting of a stellar interior region matched across a boundary to a vacuum exterior region that models the tidal field. The field equations for the metric and matter perturbations at the interior and exterior regions are complemented with corresponding boundary conditions. The data of the two problems at the common boundary are related by the so called matching conditions. These conditions for the tidal problem are known in the contexts of perfect fluid stars and superfluid stars modelled by a two-fluid. Here we review the obtaining of the matching conditions for the tidal problem starting from a purely geometrical setting, and present them so that they can be readily applied to more general contexts, such as other types of matter fields, different multiple layers or phase transitions. As a guide on how to use the matching conditions, we recover the known results for perfect fluid and superfluid neutron stars. [ABSTRACT FROM AUTHOR]

Published

2024

3. An effective model for the quantum Schwarzschild black hole.

Author

Alonso-Bardaji, Asier, Brizuela, David, and Vera, Raül

Subjects

*GENERAL relativity (Physics), *QUANTUM gravity, *PHASE space, *SPACETIME, *ALGEBRA

Abstract

We present an effective theory to describe the quantization of spherically symmetric vacuum motivated by loop quantum gravity. We include anomaly-free holonomy corrections through a canonical transformation and a linear combination of constraints of general relativity, such that the modified constraint algebra closes. The system is then provided with a fully covariant and unambiguous geometric description, independent of the gauge choice on the phase space. The resulting spacetime corresponds to a singularity-free (black-hole/white-hole) interior and two asymptotically flat exterior regions of equal mass. The interior region contains a minimal smooth spacelike surface that replaces the Schwarzschild singularity. We find the global causal structure and the maximal analytical extension. Both Minkowski and Schwarzschild spacetimes are directly recovered as particular limits of the model. [ABSTRACT FROM AUTHOR]

Published

2022