Enhancing the alignment of the optically bright Gaia reference frame with respect to the International Celestial Reference System
Loading...
Access rights
openAccess
Journal Title
Journal ISSN
Volume Title
A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
This publication is imported from Aalto University research portal.
View publication in the Research portal
View/Open full text file from the Research portal
Other link related to publication
View publication in the Research portal
View/Open full text file from the Research portal
Other link related to publication
Date
2023-08-01
Major/Subject
Mcode
Degree programme
Language
en
Pages
Series
Astronomy and Astrophysics, Volume 676
Abstract
Context. The link of the Gaia frame in terms of non-rotation with respect to the International Celestial Reference System (ICRS), which is realized via very long baseline interferometry (VLBI) at radio wavelengths, has to be conducted for the wide range of optical magnitudes in which the spacecraft observes. There is a sufficient number of suitable counterparts between the two measurement systems for optically faint objects. However, the number of common optically bright (G = 13 mag) objects is sparse as most are faint at radio frequencies, and only a few objects suitable for astrometry have been observed by VLBI in the past. As a result, rotation parameters for the optically bright Gaia reference frame are not yet determined with sufficient accuracy. Aims. The verification of the Gaia bright frame of DR2 and EDR3 is enhanced by the reevaluation of existing VLBI observations and the addition of newly acquired data for a sample of optically bright radio stars. Methods. Historical data from the literature were reevaluated, ensuring that the calibrator positions and uncertainties (used for the determination of the absolute star positions in the phase-referencing analysis) were updated and homogeneously referred to the ICRF3, the third realization of the International Celestial Reference Frame. We selected 46 suitable optically bright radio stars from the literature for new radio observations, out of which 32 were detected with the VLBA in continuum mode in the X or C band, along with radio-bright calibrators in the ICRF3. Improved Gaia-VLBI rotation parameters were obtained by adding new observations and utilizing more realistic estimates of the absolute position uncertainties for all phase-referenced radio observations. Results. The homogenization greatly improved the steadiness of the results when the most discrepant stars were rejected one after another through a dedicated iterative process. For Gaia DR2, this homogenization reduced the magnitude of the orientation parameters to less than 0.5 mas but increased that of the spin parameters, with the largest component being the rotation around the Y axis. An adjustment of the position uncertainties improved the reliability of the orientation parameters and the goodness of fit for the iterative solutions. Introducing the new single-epoch positions to the analysis reduced the correlations between the rotation parameters. The final spin for Gaia DR2 as determined by VLBI observations of radio stars is (-0.056, -0.113, +0.033) ± (0.046, 0.058, 0.053) mas yr-1. A comparison of the new results with external, independently derived spin parameters for Gaia DR2 reveals smaller differences than when using the historical data from the literature. Applying the VLBI data to Gaia EDR3, which was already corrected for spin during Gaia processing, the derived residual spin is (+0.022, +0.065, -0.016) ± (0.024, 0.026, 0.024) mas yr-1, showing that the component in Y is significant at the 2.4s level. Conclusions. Even though our analysis provides a more accurate frame tie, more VLBI data are needed to refine the results and reduce the scatter between iterative solutions.Description
Funding Information: We are grateful for the helpful support of F. Schinzel (NRAO) during AIPS data processing. We deeply thank the anonymous referee for constructive suggestions to improve the content and readability of the manuscript. The authors acknowledge use of the Very Long Baseline Array under the US Naval Observatory’s time allocation. This work supports USNO’s ongoing research into the celestial reference frame and geodesy. We thank also the Socorro correlator for reliably and quickly providing the correlated data. The National Radio Astronomy Observatory is a facility of the National Science Foundation operated under cooperative agreement by Associated Universities, Inc. This project is supported by the DFG grants no. SCHU 1103/7-2 and no. HE 5937/2-2. M.H. Xu was supported by the Academy of Finland project no. 315721. This work has made use of the data from the European Space Agency (ESA) mission Gaia processed by the Gaia Data Processing and Analysis Consortium as well as from the mission H IPPARCOS . Funding for the DPAC has been provided by national institutions, in particular the institutions participating in the Gaia Multilateral Agreement. Calibrators were selected using the NRAO VLBA calibrator search tool ( www.vlba.nrao.edu/astro/calib/ ), the RFC calibrator search tool ( www.astrogeo.org/calib/search.html ), and the Astrogeo VLBI FITS image database ( www.astrogeo.org/vlbi_images/ ). This research has made use of the VizieR catalog access tool, CDS, Strasbourg, France and the SIMBAD database (Wenger et al. 2000), operated at CDS, Strasbourg, France. Calculations were made in MATLAB which is distributed by the MathWorks, Inc. Publisher Copyright: © 2023 EDP Sciences. All rights reserved.
Keywords
Astrometry, Instrumentation: interferometers, Methods: data analysis, Methods: observational, Radio continuum: stars, Reference systems
Other note
Citation
Lunz, S, Anderson, J M, Xu, M H, Titov, O, Heinkelmann, R, Johnson, M C & Schuh, H 2023, ' Enhancing the alignment of the optically bright Gaia reference frame with respect to the International Celestial Reference System ', Astronomy and Astrophysics, vol. 676, A11 . https://doi.org/10.1051/0004-6361/202040266