Exploration of quasars with the<i>Gaia</i>mission

Proft, S.; Wambsganß, J.

doi:10.1051/0004-6361/201323280

Cited by 12 publications

(12 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Gaia will observe not only stars, but also tens of thousands of quasars, unresolved galaxies, Solar system objects, many transient and variable objects like supernovae, and finally the interstellar medium (Altavilla et al 2012;Ducourant et al 2014;Eyer et al 2014;de Bruijne et al 2015;Proft & Wambsganss 2015;Zwitter & Kos 2015;Bachchan, Hobbs, & Lindegren 2016;Tanga et al 2016). Gaia will also pose a challenge because of its data amount and complexity, pushing the astrophysical community farther into the path of big data and data mining (Gaia Collaboration 2016a).…”

Section: Introductionmentioning

confidence: 99%

Globular clusters with Gaia

Pancino

Bellazzini

Giuffrida

et al. 2017

Mon. Not. R. Astron. Soc.

View full text Add to dashboard Cite

The treatment of crowded fields in Gaia data will only be a reality in a few years from now. In particular, for globular clusters, only the end-of-mission data (public in 2022-2023) will have the necessary full crowding treatment and will reach sufficient quality for the faintest stars. As a consequence, the work on the deblending and decontamination pipelines is still ongoing. We describe the present status of the pipelines for different Gaia instruments, and we model the end-of-mission crowding errors on the basis of available information. We then apply the nominal post-launch Gaia performances, appropriately worsened by the estimated crowding errors, to a set of 18 simulated globular clusters with different concentration, distance, and field contamination. We conclude that there will be 10 3 -10 4 stars with astrometric performances virtually untouched by crowding (contaminated by <1 mmag) in the majoritiy of clusters. The most limiting factor will be field crowding, not cluster crowding: the most contaminated clusters will only contain 10-100 clean stars. We also conclude that: (i) the systemic proper motions and parallaxes will be determined to 1% or better up to 15 kpc, and the nearby clusters will have radial velocities to a few km s −1 ; (ii) internal kinematics will be of unprecendented quality, cluster masses will be determined to 10% up to 15 kpc and beyond, and it will be possible to identify differences of a few km s −1 or less in the kinematics (if any) of cluster sub-populations up to 10 kpc and beyond; (iii) the brightest stars (V 17 mag) will have space-quality, wide-field photometry (mmag errors), and all Gaia photometry will have 1-3% errors on the absolute photometric calibration.

show abstract

Section: Introductionmentioning

confidence: 99%

Globular clusters with Gaia

Pancino

Bellazzini

Giuffrida

et al. 2017

Mon. Not. R. Astron. Soc.

View full text Add to dashboard Cite

show abstract

“…Vertical stripe at ∼8,600 Å is the wavelength range of Gaia's spectroscopic instrument. In our view the figure, which summarizes simulations of Proft et al (2015), clearly demonstrates the ability of Gaia to determine photometric redshifts for a complete population of quasars down to V ∼20. For brighter objects even changes in their spectral energy distribution (SED) should be detectable.…”

Section: Gaia and Quasarsmentioning

confidence: 62%

“…For brighter objects even changes in their spectral energy distribution (SED) should be detectable. Proft et al (2015) demonstrate that variability of SDSS 154757.71+060626.6, which has Sloan red magnitude r ′ = 17.5 and redshift z = 2.03, is clearly within the reach of Gaia.…”

Section: Gaia and Quasarsmentioning

confidence: 71%

“…Magnitude and wavelength limitations of Gaia's spectroscopic instrument are being complemented by ground-based optical stellar spectroscopic surveys which are aimed to obtain stellar parameters and accurate radial velocities, as well as abundances of individual elements for FIGURE 1 | Positional error after a 5-year mission as a function of V magnitude. The latter was derived from Gaia's intrinsic G magnitude using the relation V = 1.02 G − 0.24, which is appropriate for quasars with z ≤ 4 (Proft et al, 2015). Positional error estimate assumes a point-like source and follows Equations (4-7) from Prusti et al (2016) with 0.54 < V − I < 0.98. stars which are not within the reach of Gaia.…”

Section: The Gaia Missionmentioning

confidence: 99%

See 1 more Smart Citation

Gaia Space Mission and Quasars

Zwitter

2017

Front. Astron. Space Sci.

View full text Add to dashboard Cite

“…The combination of offsets measured using Gaia and gravitational lensing will give us a complementary insight into inner regions of galaxies at all redshifts. It is also expected that Gaia can detect more than 500 000 quasars (Proft & Wambsganss 2015), and among them about 3000 gravitationally lensed quasars (Finet et al 2012). Gaia astrometry for these gravitationally lensed quasars will provide an excellent frame for comparison of mirage image positions.…”

Section: Multi-wavelength Offset Observationsmentioning

confidence: 99%

Galaxies as High-resolution Telescopes

Barnacka

2017

ApJ

View full text Add to dashboard Cite

Recent observations show a population of active galaxies with milliarcseconds offsets between optical and radio emission. Such offsets can be an indication of extreme phenomena associated with supermassive black holes including relativistic jets, binary supermassive black holes, or even recoiling supermassive black holes. However, the multi-wavelength structure of active galaxies at a few milliarcseconds cannot be resolved with direct observations. We propose using strong gravitational lensing to elucidate the multi-wavelength structure of sources. When sources are located close to the caustic of lensing galaxy, even small offset in the position of the sources results in a drastic difference in the position and magnification of mirage images. We show that the angular offset in the position of the sources can be amplified more than 50 times in the observed position of mirage images. We find that at least 8% of the observed gravitationally lensed quasars will be in the caustic configuration. The synergy between SKA and Euclid will provide an ideal set of observations for thousands of gravitationally lensed sources in the caustic configuration, which will allow us to resolve the multiwavelength structure for a large ensemble of sources, and study the physical origin of radio emissions, their connection to supermassive black holes, and their cosmic evolution.

show abstract

Exploration of quasars with theGaiamission

Cited by 12 publications

References 50 publications

Globular clusters with Gaia

Globular clusters with Gaia

Gaia Space Mission and Quasars

Galaxies as High-resolution Telescopes

Contact Info

Product

Resources

About