Your search keyword '"Vázquez Ramió, H."' showing total 3 results

1. J-NEP: 60-band photometry and photometric redshifts for the James Webb Space Telescope North Ecliptic Pole Time-Domain Field.

Author

Hernán-Caballero, A., Willmer, C. N. A., Varela, J., López-Sanjuan, C., Marín-Franch, A., Vázquez Ramió, H., Civera, T., Ederoclite, A., Muniesa, D., Cenarro, J., Bonoli, S., Dupke, R., Lim, J., Chaves-Montero, J., Laur, J., Hernández-Monteagudo, C., Fernández-Ontiveros, J. A., Fernández-Soto, A., Díaz-García, L. A., and González Delgado, R. M.

Subjects

SPACE telescopes, PHOTOMETRY, EXPANDING universe, STANDARD deviations, REDSHIFT, OBSERVATORIES

Abstract

The Javalambre-Physics of the Accelerating Universe Astrophysical Survey (J-PAS) will observe approximately one-third of the northern sky with a set of 56 narrow-band filters using the dedicated 2.55 m Javalambre Survey Telescope (JST) at the Javalambre Astrophysical Observatory. Prior to the installation of the main camera, in order to demonstrate the scientific potential of J-PAS, two small surveys were performed with the single-CCD Pathfinder camera: miniJPAS (~1 deg2 along the Extended Groth Strip), and J-NEP (~0.3 deg2 around the JWST North Ecliptic Pole Time Domain Field), including all 56 J-PAS filters as well as u, g, r, and i. J-NEP is ~0.5–1.0 mag deeper than miniJPAS, providing photometry for 24,618 r-band-detected sources and photometric redshifts (photo-z) for the 6662 sources with r < 23. In this paper, we describe the photometry and photo-z of J-NEP and demonstrate a new method for the removal of systematic offsets in the photometry based on the median colours of galaxies, which we call 'galaxy locus recalibration'. This method does not require spectroscopic observations except in a few reference pointings and, unlike previous methods, is directly applicable to the whole J-PAS survey. We use a spectroscopic sample of 787 galaxies to test the photo-z performance for J-NEP and in comparison to miniJPAS. We find that the deeper J-NEP observations result in a factor ~1.5–2 decrease in σNMAD (a robust estimate of the standard deviation of the photo-z error) and η (the outlier rate) relative to miniJPAS for r > 21.5 sources, but no improvement in brighter ones, which is probably because of systematic uncertainties. We find the same relation between σNMAD and odds in J-NEP and miniJPAS, which suggests that we will be able to predict the σNMAD of any set of J-PAS sources from their odds distribution alone, with no need for additional spectroscopy to calibrate the relation. We explore the causes of photo-z outliers and find that colour-space degeneracy at low S/N, photometry artefacts, source blending, and exotic spectra are the most important factors. [ABSTRACT FROM AUTHOR]

Published

2023

2. The GALANTE photometric survey of the northern Galactic plane: project description and pipeline.

Author

Maíz Apellániz, J, Alfaro, E J, Barbá, R H, Holgado, G, Vázquez-Ramió, H, Varela, J, Ederoclite, A, Lorenzo-Gutiérrez, A, García-Lario, P, García Escudero, H, García, M, and Coelho, P R T

Subjects

AIR masses, SIGNAL-to-noise ratio, ELECTRONIC data processing, GOAL (Psychology), PHOTOMETRY

Abstract

The GALANTE optical photometric survey is observing the northern Galactic plane and some adjacent regions using seven narrow- and intermediate-filters, covering a total of 1618 deg2. The survey has been designed with multiple exposure times and at least two different air masses per field to maximize its photometric dynamic range, comparable to that of Gaia , and ensure the accuracy of its photometric calibration. The goal is to reach at least 1 per cent accuracy and precision in the seven bands for all stars brighter than AB magnitude 17 while detecting fainter stars with lower values of the signal-to-noise ratio. The main purposes of GALANTE are the identification and study of extinguished O+B+WR stars, the derivation of their extinction characteristics, and the cataloguing of F and G stars in the solar neighbourhood. Its data will be also used for a variety of other stellar studies and to generate a high-resolution continuum-free map of the H α emission in the Galactic plane. We describe the techniques and the pipeline that are being used to process the data, including the basis of an innovative calibration system based on Gaia  DR2 and 2MASS photometry. [ABSTRACT FROM AUTHOR]

Published

2021

3. Deriving stellar parameters from GALANTE photometry: bias and precision.

Author

Lorenzo-Gutiérrez, A, Alfaro, E J, Maíz Apellániz, J, Barbá, R H, Marín-Franch, A, Ederoclite, A, Cristóbal-Hornillos, D, Varela, J, Vázquez Ramió, H, Cenarro, A J, Lennon, D J, García-Lario, P, Daflon, S, and Borges Fernandes, M

Subjects

PHOTOMETRY, STELLAR photometry, DATA libraries, STAR formation, GALAXY formation

Abstract

In this paper, we analyse how to extract the physical properties from the GALANTE photometry of a stellar sample. We propose a direct comparison between the observational colours (photometric bands normalized to the 515 nm central wavelength) and the synthetic colours derived from different stellar libraries. We use the reduced χ2 as the figure of merit for selecting the best fitting between both colour sets. The synthetic colours of the Next Generation Spectral Library (NGSL) provide a valuable sample for testing the uncertainty and precision of the stellar parameters derived from observational data. Reddening, as an extrinsic stellar physical parameter becomes a crucial variable for accounting for the errors and bias in the derived estimates: the higher the reddenings, the larger the errors and uncertainties in the derived parameters. NGSL colours also enable us to compare different theoretical stellar libraries for the same set of physical parameters, where we see how different catalogues of models can provide very different solutions in a, sometimes, non-linear way. This peculiar behaviour makes us to be cautious with the derived physical parameters obtained from GALANTE photometry without previous detailed knowledge of the theoretical libraries used to this end. In addition, we carry out the experiment of deriving physical stellar parameters from some theoretical libraries, using some other libraries as observational data. In particular, we use the Kurucz and Coelho libraries, as input observational data, to derive stellar parameters from Coelho + TLUSTY and Kurucz + TLUSTY stellar libraries, respectively, for different photometric errors and colour excesses. [ABSTRACT FROM AUTHOR]

Published

2020