Your search keyword '"Mascareño, A. Suárez"' showing total 5 results

1. Fundamental physics with ESPRESSO: a new determination of the D/H ratio towards PKS1937-101

Author

Guarneri, Francesco, Pasquini, Luca, D'Odorico, Valentina, Cristiani, Stefano, Cupani, Guido, Di Marcantonio, Paolo, Hernández, J. I. González, Martins, C. J. A. P., Mascareño, Alejandro Suárez, Milaković, Dinko, Molaro, Paolo, Murphy, Michael T., Nunes, Nelson J., Palle, Enric, Pepe, Francesco, Rebolo, Rafael, Santos, Nuno C., Santos, Ricardo Génova, Schmidt, Tobias M., Sousa, Sérgio G., Sozzetti, Alessandro, and Trost, Andrea

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Primordial abundances of light elements are sensitive to the physics of the early Universe and can directly constrain cosmological quantities, such as the baryon-to-photon ratio $\eta_{10}$, the baryon density and the number of neutrino families. Deuterium is especially suited for these studies: its primordial abundance is sensitive and monotonically dependent on $\eta_{10}$, allowing an independent measurement of the cosmic baryon density that can be compared, for instance, against the Planck satellite data. The primordial deuterium abundance can be measured in high $H_I$ column density absorption systems towards distant quasars. We report here a new measurement, based on high-resolution ESPRESSO data, of the primordial $D_I$ abundance of a system at redshift $z \sim 3.572$, towards PKS1937-101. Using only ESPRESSO data, we find a D/H ratio of $2.638\pm0.128 \times 10^{-5}$, while including the available UVES data improves the precision, leading to a ratio of $2.608 \pm 0.102 \times 10^{-5}$. The results of this analysis agree with those of the most precise existing measurements. We find that the relatively low column density of this system ($\log{N_{\rm H_I}/ {\rm cm}^{-2}}\sim18 $) introduces modelling uncertainties, which become the main contributor to the error budget., Comment: Accepted for publication in MNRAS. 16 pages, 10 figures and 6 tables (4 in main text, 2 in Appendix). Full model is available at the end of the manuscript

Published

2024

2. Fundamental physics with ESPRESSO: Constraints on Bekenstein and dark energy models from astrophysical and local probes

Author

Martins, C. J. A. P., Cristiani, S., Cupani, G., D'Odorico, V., Santos, R. Génova, Leite, A. C. O., Marques, C. M. J., Milaković, D., Molaro, P., Murphy, Michael T., Nunes, N. J., Schmidt, Tobias M., Adibekyan, V., Alibert, Y., Di Marcantonio, Paolo, Hernández, J. I. González, Mégevand, D., Palle, E., Pepe, F. A., Santos, N. C., Sousa, S. G., Sozzetti, A., Mascareño, A. Suárez, and Osorio, M. R. Zapatero

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Phenomenology

Abstract

Dynamical scalar fields in an effective four-dimensional field theory are naturally expected to couple to the rest of the theory's degrees of freedom, unless some new symmetry is postulated to suppress these couplings. In particular, a coupling to the electromagnetic sector will lead to spacetime variations of the fine-structure constant, $\alpha$. Astrophysical tests of the space-time stability of $\alpha$ are therefore a powerful probe of new physics. Here we use ESPRESSO and other contemporary measurements of $\alpha$, together with background cosmology data, local laboratory atomic clock and Weak Equivalence Principle measurements, to place stringent constraints on the simplest examples of the two broad classes of varying $\alpha$ models: Bekenstein models and quintessence-type dark energy models, both of which are parametric extensions of the canonical $\Lambda$CDM model. In both cases, previously reported constraints are improved by more than a factor of ten. This improvement is largely due to the very strong local constraints, but astrophysical measurements can help to break degeneracies between cosmology and fundamental physics parameters., Comment: 8 pages, 2 figures, 2 tables; in press at Phys. Rev. D

Published

2022

3. Fundamental Physics with ESPRESSO, Constraining a simple parametrisation for varying $\alpha$

Author

da Fonseca, Vitor, Barreiro, Tiago, Nunes, Nelson J., Cristiani, Stefano, Cupani, Guido, D'Odorico, Valentina, Santos, Ricardo Génova, Leite, Ana C. O., Marques, Catarina M. J., Martins, Carlos J. A. P., Milaković, Dinko, Molaro, Paolo, Murphy, Michael T., Schmidt, Tobias M., Abreu, Manuel, Adibekyan, Vardan, Cabral, Alexandre, Di Marcantonio, Paolo, Hernández, Jonay I. González, Palle, Enric, Pepe, Francesco A., Rebolo, Rafael, Santos, Nuno C., Sousa, Sérgio G., Sozzetti, Alessandro, Mascareño, Alejandro Suárez, and Osorio, Maria-Rosa Zapatero

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

The spectrograph ESPRESSO recently obtained a limit on the variation of the fine-structure constant, $\alpha$, through measurements along the line of sight of a bright quasar with a precision of $1.36$ ppm at $1\sigma$ level. This imposes new constraints on cosmological models with a varying $\alpha$. We assume such a model where the electromagnetic sector is coupled to a scalar field dark energy responsible for the current acceleration of the Universe. We parametrise the variation of $\alpha$ with two extra parameters, one defining the cosmological evolution of the quintessence component and the other fixing the coupling with the electromagnetic field. The objective of this work is to constrain these parameters with both astrophysical and local probes. We also carried out a comparative analysis of how each data probe may constrain our parametrisation. We performed a Bayesian analysis by comparing the predictions of the model with observations. The astrophysical datasets are composed of quasar spectra measurements, including the latest ESPRESSO data point, as well as Planck observations of the cosmic microwave background. We combined these with local results from atomic clocks and the MICROSCOPE experiment. The constraints placed on the quintessence parameter are consistent with a null variation of the field, and are therefore compatible with a $\Lambda$CDM cosmology. The constraints on the coupling to the electromagnetic sector are dominated by the E\"otv\"os parameter local bound. More precise measurements with ESPRESSO will be extremely important to study the cosmological evolution of $\alpha$ as it probes an interval of redshift not accessible to other types of observations. However, for this particular model, current available data favour a null variation of $\alpha$ resulting mostly from the strong MICROSCOPE limits., Comment: 9 pages, 7 figures, as published in A&A

Published

2022

4. Fundamental physics with ESPRESSO: Precise limit on variations in the fine-structure constant towards the bright quasar HE 0515$-$4414

Author

Murphy, Michael T., Molaro, Paolo, Leite, Ana C. O., Cupani, Guido, Cristiani, Stefano, D'Odorico, Valentina, Santos, Ricardo Génova, Martins, Carlos J. A. P., Milaković, Dinko, Nunes, Nelson J., Schmidt, Tobias M., Pepe, Francesco A., Rebolo, Rafael, Santos, Nuno C., Sousa, Sérgio G., Osorio, Maria-Rosa Zapatero, Amate, Manuel, Adibekyan, Vardan, Alibert, Yann, Prieto, Carlos Allende, Baldini, Veronica, Benz, Willy, Bouchy, François, Cabral, Alexandre, Dekker, Hans, Di Marcantonio, Paolo, Ehrenreich, David, Figueira, Pedro, Hernández, Jonay I. González, Landoni, Marco, Lovis, Christophe, Curto, Gaspare Lo, Manescau, Antonio, Mégevand, Denis, Mehner, Andrea, Micela, Giuseppina, Pasquini, Luca, Poretti, Ennio, Riva, Marco, Sozzetti, Alessandro, Mascareño, Alejandro Suárez, Udry, Stéphane, and Zerbi, Filippo

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

The strong intervening absorption system at redshift 1.15 towards the very bright quasar HE 0515$-$4414 is the most studied absorber for measuring possible cosmological variations in the fine-structure constant, $\alpha$. We observed HE 0515$-$4414 for 16.1$\,$h with the Very Large Telescope and present here the first constraint on relative variations in $\alpha$ with parts-per-million (ppm) precision from the new ESPRESSO spectrograph: $\Delta\alpha/\alpha = 1.3 \pm 1.3_{\rm stat} \pm 0.4_{\rm sys}\,{\rm ppm}$. The statistical uncertainty (1$\sigma$) is similar to the ensemble precision of previous large samples of absorbers, and derives from the high S/N achieved ($\approx$105 per 0.4$\,$km$\,$s$^{-1}$ pixel). ESPRESSO's design, and calibration of our observations with its laser frequency comb, effectively removed wavelength calibration errors from our measurement. The high resolving power of our ESPRESSO spectrum ($R=145000$) enabled the identification of very narrow components within the absorption profile, allowing a more robust analysis of $\Delta\alpha/\alpha$. The evidence for the narrow components is corroborated by their correspondence with previously detected molecular hydrogen and neutral carbon. The main remaining systematic errors arise from ambiguities in the absorption profile modelling, effects from redispersing the individual quasar exposures, and convergence of the parameter estimation algorithm. All analyses of the spectrum, including systematic error estimates, were initially blinded to avoid human biases. We make our reduced ESPRESSO spectrum of HE 0515$-$4414 publicly available for further analysis. Combining our ESPRESSO result with 28 measurements, from other spectrographs, in which wavelength calibration errors have been mitigated, yields a weighted mean $\Delta\alpha/\alpha = -0.5 \pm 0.5_{\rm stat} \pm 0.4_{\rm sys}\,$ppm at redshifts 0.6-2.4., Comment: Accepted by A&A. The ESPRESSO quasar spectrum, reduced contributing exposures, and absorption profile fits are available at https://github.com/MTMurphy77/ESPRESSO_HE0515-4414

Published

2021

5. Fundamental physics with Espresso: Towards an accurate wavelength calibration for a precision test of the fine-structure constant

Author

Schmidt, Tobias M., Molaro, Paolo, Murphy, Michael T., Lovis, Christophe, Cupani, Guido, Cristiani, Stefano, Pepe, Francesco A., Rebolo, Rafael, Santos, Nuno C., Abreu, Manuel, Adibekyan, Vardan, Alibert, Yann, Aliverti, Matteo, Allart, Romain, Prieto, Carlos Allende, Alves, David, Baldini, Veronica, Broeg, Christopher, Cabral, Alexandre, Calderone, Giorgio, Cirami, Roberto, Coelho, João, Coretti, Igor, D'Odorico, Valentina, Di Marcantonio, Paolo, Ehrenreich, David, Figueira, Pedro, Genoni, Matteo, Santos, Ricardo Génova, Hernández, Jonay I. González, Kerber, Florian, Landoni, Marco, Leite, Ana C. O., Lizon, Jean-Louis, Curto, Gaspare Lo, Manescau, Antonio, Martins, Carlos J. A. P., Megévand, Denis, Mehner, Andrea, Micela, Giuseppina, Modigliani, Andrea, Monteiro, Manuel, Monteiro, Mario J. P. F. G., Mueller, Eric, Nunes, Nelson J., Oggioni, Luca, Oliveira, António, Pariani, Giorgio, Pasquini, Luca, Redaelli, Edoardo, Riva, Marco, Santos, Pedro, Sosnowska, Danuta, Sousa, Sérgio G., Sozzetti, Alessandro, Mascareño, Alejandro Suárez, Udry, Stéphane, Osorio, Maria-Rosa Zapatero, and Zerbi, Filippo

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

Observations of metal absorption systems in the spectra of distant quasars allow to constrain a possible variation of the fine-structure constant throughout the history of the Universe. Such a test poses utmost demands on the wavelength accuracy and previous studies were limited by systematics in the spectrograph wavelength calibration. A substantial advance in the field is therefore expected from the new ultra-stable high-resolution spectrograph Espresso, recently installed at the VLT. In preparation of the fundamental physics related part of the Espresso GTO program, we present a thorough assessment of the Espresso wavelength accuracy and identify possible systematics at each of the different steps involved in the wavelength calibration process. Most importantly, we compare the default wavelength solution, based on the combination of Thorium-Argon arc lamp spectra and a Fabry-P\'erot interferometer, to the fully independent calibration obtained from a laser frequency comb. We find wavelength-dependent discrepancies of up to 24m/s. This substantially exceeds the photon noise and highlights the presence of different sources of systematics, which we characterize in detail as part of this study. Nevertheless, our study demonstrates the outstanding accuracy of Espresso with respect to previously used spectrographs and we show that constraints of a relative change of the fine-structure constant at the $10^{-6}$ level can be obtained with Espresso without being limited by wavelength calibration systematics., Comment: 27 pages, accepted for publication in A&A

Published

2020