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Gaia (spacecraft)

January 13, 2023

Gaia is a space observatory of the European Space Agency (ESA), launched in 2013 and expected to operate until 2025. The spacecraft is designed for astrometry: measuring the positions, distances and motions of stars with unprecedented precision.[5][6] The mission aims to construct by far the largest and most precise 3D space catalog ever made, totalling approximately 1 billion astronomical objects, mainly stars, but also planets, comets, asteroids and quasars, among others.[7]

Gaia
Artist's impression of the Gaia spacecraft
Mission typeAstrometric observatory
OperatorESA
COSPAR ID2013-074A
SATCAT no.39479
Websitesci.esa.int/gaia/
Mission duration9 years and 24 days (in progress)
Spacecraft properties
Manufacturer
Launch mass2,029 kg (4,473 lb)[1]
Dry mass1,392 kg (3,069 lb)
Payload mass710 kg (1,570 lb)[2]
Dimensions4.6 m × 2.3 m (15.1 ft × 7.5 ft)
Power1,910 watts
Start of mission
Launch date19 December 2013, 09:12:14 UTC (2013-12-19UTC09:12:14Z)[3]
RocketSoyuz ST-B/Fregat-MT
Launch siteKourou ELS
ContractorArianespace
Orbital parameters
Reference systemSun–Earth L2
RegimeLissajous orbit
Periapsis altitude263,000 km (163,000 mi)[4]
Apoapsis altitude707,000 km (439,000 mi)[4]
Period180 days
Epoch2014
Main telescope
TypeThree-mirror anastigmat[1]
Diameter1.45 m × 0.5 m (4 ft 9 in × 1 ft 8 in)
Collecting area0.7 m2
Transponders
Band
Bandwidth
  • a few kbit/s down & up (S Band)
  • 3–8 Mbit/s download (X Band)
Instruments
  • ASTRO: Astrometric instrument
  • BP/RP: Photometric instrument
  • RVS: Radial velocity spectrometer

ESA astrophysics insignia for Gaia  

To study the precise position and motion of its target objects, the spacecraft monitored each of them about 70 times[8] over the five years of the nominal mission (2014–2019), and continues to do so during its extension.[9][10] The spacecraft has enough micro-propulsion fuel to operate until about November 2024.[11] As its detectors are not degrading as fast as initially expected, the mission could therefore be extended.[12] Gaia targets objects brighter than magnitude 20 in a broad photometric band that covers the extended visual range between near-UV and near infrared;[13] such objects represent approximately 1% of the Milky Way population.[8] Additionally, Gaia is expected to detect thousands to tens of thousands of Jupiter-sized exoplanets beyond the Solar System by using the astrometry method,[14][15] 500,000 quasars outside this galaxy and tens of thousands of known and new asteroids and comets within the Solar System.[16][17][18]

The Gaia mission will create a precise three-dimensional map of astronomical objects throughout the Milky Way and map their motions, which encode the origin and subsequent evolution of the Milky Way. The spectrophotometric measurements will provide the detailed physical properties of all stars observed, characterizing their luminosity, effective temperature, gravity and elemental composition. This massive stellar census will provide the basic observational data to analyze a wide range of important questions related to the origin, structure and evolutionary history of the Milky Way galaxy.

The successor to the Hipparcos mission (operational 1989–1993), Gaia is part of ESA's Horizon 2000+ long-term scientific program. Gaia was launched on 19 December 2013 by Arianespace using a Soyuz ST-B/Fregat-MT rocket flying from Kourou in French Guiana.[19][20] The spacecraft currently operates in a Lissajous orbit around the SunEarth L2 Lagrangian point.

History

The Gaia space telescope has its roots in ESA's Hipparcos mission (1989–1993). Its mission was proposed in October 1993 by Lennart Lindegren (Lund Observatory, Lund University, Sweden) and Michael Perryman (ESA) in response to a call for proposals for ESA's Horizon Plus long-term scientific programme. It was adopted by ESA's Science Programme Committee as cornerstone mission number 6 on 13 October 2000, and the B2 phase of the project was authorised on 9 February 2006, with EADS Astrium taking responsibility for the hardware. The name "Gaia" was originally derived as an acronym for Global Astrometric Interferometer for Astrophysics. This reflected the optical technique of interferometry that was originally planned for use on the spacecraft. While the working method evolved during studies and the acronym is no longer applicable, the name Gaia remained to provide continuity with the project.[21]

The total cost of the mission is around €740 million (~ $1 billion), including the manufacture, launch and ground operations.[22] Gaia was completed two years behind schedule and 16% above its initial budget, mostly due to the difficulties encountered in polishing Gaia's ten silicon carbide mirrors and assembling and testing the focal plane camera system.[23]

Objectives

The Gaia space mission has the following objectives:

  • To determine the intrinsic luminosity of a star requires knowledge of its distance. One of the few ways to achieve this without physical assumptions is through the star's parallax, but atmospheric effects and instrumental biases degrade the precision of parallax measurements. For instance, Cepheid variables are used as standard candles to measure distances to galaxies, but their own distances are poorly known. Thus, quantities depending on them, such as the speed of expansion of the universe, remain inaccurate. Measuring their distances accurately has a great impact on the understanding of the other galaxies and thus the whole cosmos (see cosmic distance ladder).
  • Observations of the faintest objects will provide a more complete view of the stellar luminosity function. Gaia will observe 1 billion stars and other bodies, representing 1% of such bodies in the Milky Way galaxy.[23] All objects up to a certain magnitude must be measured in order to have unbiased samples.
  • To permit a better understanding of the more rapid stages of stellar evolution (such as the classification, frequency, correlations and directly observed attributes of rare fundamental changes and of cyclical changes). This has to be achieved by detailed examination and re-examination of a great number of objects over a long period of operation. Observing a large number of objects in the galaxy is also important to understand the dynamics of this galaxy.
  • Measuring the astrometric and kinematic properties of a star is necessary in order to understand the various stellar populations, especially the most distant.

In order to achieve these objectives, Gaia has these goals:

  • Determine the position, parallax and annual proper motion of 1 billion stars with an accuracy of about 20 microarcseconds (μas) at 15 mag, and 200 μas at 20 mag.
  • Determine the positions of stars at a magnitude of V = 10 down to a precision of 7 μas—this is equivalent to measuring the position to within the diameter of a hair from 1000 km away—between 12 and 25 μas down to V = 15, and between 100 and 300 μas to V = 20, depending on the colour of the star.
  • The distance to about 20 million stars will thus be measured with a precision of 1% or better, and about 200 million distances will be measured to better than 10%. Distances accurate to 10% will be achieved as far away as the Galactic Center, 30,000 light-years away.[24]
  • Measure the tangential speed of 40 million stars to a precision of better than 0.5 km/s.
  • Derive the atmospheric parameters (effective temperature, line-of-sight interstellar extinction, surface gravity, metallicity) for all stars observed,[25] plus some more detailed chemical abundances for targets brighter than V = 15.[26]
  • Measure the orbits and inclinations of a thousand extrasolar planets accurately, determining their true mass using astrometric planet detection methods.[27][28]
  • More precisely measure the bending of starlight by the Sun's gravitational field, predicted by Albert Einstein's General Theory of Relativity and first detected by Arthur Eddington during a 1919 solar eclipse, and therefore directly observe the structure of spacetime.[21]
  • Potential to discover Apohele asteroids with orbits that lie between Earth and the Sun, a region that is difficult for Earth-based telescopes to monitor since this region is only visible in the sky during or near the daytime.[29]
  • Detect up to 500,000 quasars.

Spacecraft

 
Model of Gaia at Paris Air Show 2013
 
Gaia at its final phase of construction, 2013

Gaia was launched by Arianespace, using a Soyuz ST-B rocket with a Fregat-MT upper stage, from the Ensemble de Lancement Soyouz at Kourou in French Guiana on 19 December 2013 at 09:12 UTC (06:12 local time). The satellite separated from the rocket's upper stage 43 minutes after launch at 09:54 UTC.[30][31] The craft headed towards the Sun–Earth Lagrange point L2 located approximately 1.5 million kilometres from Earth, arriving there 8 January 2014.[32] The L2 point provides the spacecraft with a very stable gravitational and thermal environment. There it uses a Lissajous orbit that avoids blockage of the Sun by the Earth, which would limit the amount of solar energy the satellite could produce through its solar panels, as well as disturb the spacecraft's thermal equilibrium. After launch, a 10-metre-diameter sunshade was deployed. The sunshade always faces the Sun, thus keeping all telescope components cool and powering Gaia using solar panels on its surface.

Scientific instruments

The Gaia payload consists of three main instruments:

  1. The astrometry instrument (Astro) precisely determines the positions of all stars brighter than magnitude 20 by measuring their angular position.[13] By combining the measurements of any given star over the five-year mission, it will be possible to determine its parallax, and therefore its distance, and its proper motion—the velocity of the star projected on the plane of the sky.
  2. The photometric instrument (BP/RP) allows the acquisition of luminosity measurements of stars over the 320–1000 nm spectral band, of all stars brighter than magnitude 20.[13] The blue and red photometers (BP/RP) are used to determine stellar properties such as temperature, mass, age and elemental composition.[21][33] Multi-colour photometry is provided by two low-resolution fused-silica prisms dispersing all the light entering the field of view in the along-scan direction prior to detection. The Blue Photometer (BP) operates in the wavelength range 330–680 nm; the Red Photometer (RP) covers the wavelength range 640–1050 nm.[34]
  3. The Radial-Velocity Spectrometer (RVS) is used to determine the velocity of celestial objects along the line of sight by acquiring high-resolution spectra in the spectral band 847–874 nm (field lines of calcium ion) for objects up to magnitude 17. Radial velocities are measured with a precision between 1 km/s (V=11.5) and 30 km/s (V=17.5). The measurements of radial velocities are important to correct for perspective acceleration which is induced by the motion along the line of sight."[34] The RVS reveals the velocity of the star along the line of sight of Gaia by measuring the Doppler shift of absorption lines in a high-resolution spectrum.

In order to maintain the fine pointing to focus on stars many light years away, the only moving parts are actuators to align the mirrors and the valves to fire the thrusters. It has no reaction wheels or gyroscopes. The spacecraft subsystems are mounted on a rigid silicon carbide frame, which provides a stable structure that will not expand or contract due to temperature. Attitude control is provided by small cold gas thrusters that can output 1.5 micrograms of nitrogen per second.

The telemetric link with the satellite is about 3 Mbit/s on average, while the total content of the focal plane represents several Gbit/s. Therefore, only a few dozen pixels around each object can be downlinked.

 
Diagram of Gaia
Mirrors (M)
  • Mirrors of telescope 1 (M1, M2 and M3)
  • Mirrors of telescope 2 (M'1, M'2 and M'3)
  • mirrors M4, M'4, M5, M6 are not shown
Other components (1–9)
  1. Optical bench (silicon carbide torus)
  2. Focal plane cooling radiator
  3. Focal plane electronics[35]
  4. Nitrogen tanks
  5. Diffraction grating spectroscope
  6. Liquid propellant tanks
  7. Star trackers
  8. Telecommunication panel and batteries
  9. Main propulsion subsystem
(A) Light path of telescope 1
 
Design of the focal plane and instruments

The design of the Gaia focal plane and instruments. Due to the spacecraft's rotation, images cross the focal plane array right-to-left at 60 arcseconds per second.[35]

  1. Incoming light from mirror M3
  2. Incoming light from mirror M'3
  3. Focal plane, containing the detector for the Astrometric instrument in light blue, Blue Photometer in dark blue, Red Photometer in red, and Radial Velocity Spectrometer in pink
  4. Mirrors M4 and M'4, which combine the two incoming beams of light
  5. Mirror M5
  6. Mirror M6, which illuminates the focal plane
  7. Optics and diffraction grating for the Radial Velocity Spectrometer (RVS)
  8. Prisms for the Blue Photometer and Red Photometer (BP and RP)

Measurement principles

 
Comparison of nominal sizes of apertures of the Gaia (spacecraft) and some notable optical telescopes
 
Scanning method

Similar to its predecessor Hipparcos, but with a precision one hundred times better, Gaia consists of two telescopes providing two observing directions with a fixed, wide angle of 106.5° between them.[36] The spacecraft rotates continuously around an axis perpendicular to the two telescopes' lines of sight. The spin axis in turn has a slight precession across the sky, while maintaining the same angle to the Sun. By precisely measuring the relative positions of objects from both observing directions, a rigid system of reference is obtained.

The two key telescope properties are:

  • 1.45 × 0.5 m primary mirror for each telescope
  • 1.0 × 0.5 m focal plane array on which light from both telescopes is projected. This in turn consists of 106 CCDs of 4500 × 1966 pixels each, for a total of 937.8 megapixels (commonly depicted as a gigapixel-class imaging device).[37][38][39]

Each celestial object was observed on average about 70 times during the five years of the nominal mission, which has been extended to approximately ten years and will thus obtain twice as many observations.[40] These measurements will help determine the astrometric parameters of stars: two corresponding to the angular position of a given star on the sky, two for the derivatives of the star's position over time (motion) and lastly, the star's parallax from which distance can be calculated. The radial velocity of the brighter stars is measured by an integrated spectrometer observing the Doppler effect. Because of the physical constraints imposed by the Soyuz spacecraft, Gaia's focal arrays could not be equipped with optimal radiation shielding, and ESA expected their performance to suffer somewhat toward the end of the initial five-year mission. Ground tests of the CCDs while they were subjected to radiation provided reassurance that the primary mission's objectives can be met.[41]

The expected accuracies of the final catalogue data have been calculated following in-orbit testing, taking into account the issues of stray light, degradation of the optics, and the basic angle instability. The best accuracies for parallax, position and proper motion are obtained for the brighter observed stars, apparent magnitudes 3–12. The standard deviation for these stars is expected to be 6.7 micro-arcseconds or better. For fainter stars, error levels increase, reaching 26.6 micro-arcseconds error in the parallax for 15th-magnitude stars, and several hundred micro-arcseconds for 20th-magnitude stars.[42] For comparison, the best parallax error levels from the new Hipparcos reduction are no better than 100 micro-arcseconds, with typical levels several times larger.[43]

Data processing

 
VST snaps Gaia en route to a billion stars[44]

The overall data volume that was retrieved from the spacecraft during the nominal five-year mission at a compressed data rate of 1 Mbit/s is approximately 60 TB, amounting to about 200 TB of usable uncompressed data on the ground, stored in an InterSystems Caché database. The responsibility of the data processing, partly funded by ESA, is entrusted to a European consortium, the Data Processing and Analysis Consortium (DPAC), which was selected after its proposal to the ESA Announcement of Opportunity released in November 2006. DPAC's funding is provided by the participating countries and has been secured until the production of Gaia's final catalogue.[45]

Gaia sends back data for about eight hours every day at about 5 Mbit/s. ESA's three 35-metre-diameter radio dishes of the ESTRACK network in Cebreros, Spain, Malargüe, Argentina and New Norcia, Australia, receive the data.[21]

Launch and orbit

Animation of Gaia's trajectory
 
Polar view
 
Equatorial view
 
Viewed from the Sun
  Gaia ·   Earth
 
Simplified illustration of Gaia's trajectory and orbit (not to scale)

In October 2013 ESA had to postpone Gaia's original launch date, due to a precautionary replacement of two of Gaia's transponders. These are used to generate timing signals for the downlink of science data. A problem with an identical transponder on a satellite already in orbit motivated their replacement and reverification once incorporated into Gaia. The rescheduled launch window was from 17 December 2013 to 5 January 2014, with Gaia slated for launch on 19 December.[46]

Gaia was successfully launched on 19 December 2013 at 09:12 UTC.[47] About three weeks after launch, on 8 January 2014, it reached its designated orbit around the Sun-Earth L2 Lagrange point (SEL2),[4][48] about 1.5 million kilometers from Earth.

In 2015, the Pan-STARRS observatory discovered an object orbiting the Earth, which the Minor Planet Center catalogued as object 2015 HP116. It was soon found to be an accidental rediscovery of the Gaia spacecraft and the designation was promptly retracted.[49]

Stray light problem

Shortly after launch, ESA revealed that Gaia was suffering from a stray light problem. The problem was initially thought to be due to ice deposits causing some of the light diffracted around the edges of the sunshield and entering the telescope apertures to be reflected towards the focal plane.[50] The actual source of the stray light was later identified as the fibers of the sunshield, protruding beyond the edges of the shield.[51] This results in a "degradation in science performance [which] will be relatively modest and mostly restricted to the faintest of Gaia's one billion stars." Mitigation schemes are being implemented[52] to improve performance. The degradation is more severe for the RVS spectrograph than for the astrometry measurements, because it spreads the light of the star onto a much larger number of detector pixels which each collect scattered light.

This kind of problem has some historical background. In 1985 on STS-51-F, the Space Shuttle Spacelab-2 mission, another astronomical mission hampered by stray debris was the Infrared Telescope (IRT), in which a piece of mylar insulation broke loose and floated into the line-of-sight of the telescope causing corrupted data.[53] The testing of stray-light and baffles is a noted part of space imaging instruments.[54]

Mission progress

 
Gaia map of the sky by star density.

The testing and calibration phase, which started while Gaia was en route to SEL2 point, continued until the end of July 2014,[55] three months behind schedule due to unforeseen issues with stray light entering the detector. After the six-month commissioning period, the satellite started its nominal five-year period of scientific operations on 25 July 2014 using a special scanning mode that intensively scanned the region near the ecliptic poles; on 21 August 2014 Gaia began using its normal scanning mode which provides more uniform coverage.[56]

Although it was originally planned to limit Gaia's observations to stars fainter than magnitude 5.7, tests carried out during the commissioning phase indicated that Gaia could autonomously identify stars as bright as magnitude 3. When Gaia entered regular scientific operations in July 2014, it was configured to routinely process stars in the magnitude range 3 – 20.[57] Beyond that limit, special procedures are used to download raw scanning data for the remaining 230 stars brighter than magnitude 3; methods to reduce and analyse these data are being developed; and it is expected that there will be "complete sky coverage at the bright end" with standard errors of "a few dozen μas".[58]

In 2018 the Gaia mission was extended to 2020. In 2020 the Gaia mission was further extended through 2022, with an additional "indicative extension" extending through 2025.[59][60] The limiting factor to further mission extensions is the supply of nitrogen for the cold gas thrusters of the micro-propulsion system, which is expected to last until November 2024.[11] The amount of dinitrogen tetroxide (NTO) and monomethylhydrazine (MMH) for the chemical propulsion subsystem on board might be enough to stabilize the spacecraft at L2 for several decades. Without the cold gas the space craft can no longer be pointed on a microarcsecond scale.

On 12 September 2014, Gaia discovered its first supernova in another galaxy.[61] On 3 July 2015, a map of the Milky Way by star density was released, based on data from the spacecraft.[62] As of August 2016, "more than 50 billion focal plane transits, 110 billion photometric observations and 9.4 billion spectroscopic observations have been successfully processed."[63]

Data releases

Main article: Gaia catalogues

Several Gaia catalogues are released over the years each time with increasing amounts of information and better astrometry; the early releases also miss some stars, especially fainter stars located in dense star fields and members of close binary pairs.[64] The first data release, Gaia DR1, based on only 14 months of observation was on 14 September 2016[65][66] and is described in Astronomy and Astrophysics.[67] The data release includes "positions and ... magnitudes for 1.1 billion stars using only Gaia data; positions, parallaxes and proper motions for more than 2 million stars" based on a combination of Gaia and Tycho-2 data for those objects in both catalogues; "light curves and characteristics for about 3,000 variable stars; and positions and magnitudes for more than 2000 ... extragalactic sources used to define the celestial reference frame".[64][68][69] Data from this DR1 release can be accessed at the Gaia archive,[70] as well as through astronomical data centers such as CDS.

The second data release (DR2), which occurred on 25 April 2018,[7][71] is based on 22 months of observations made between 25 July 2014 and 23 May 2016. It includes positions, parallaxes and proper motions for about 1.3 billion stars and positions of an additional 300 million stars in the magnitude range g = 3–20,[72] red and blue photometric data for about 1.1 billion stars and single colour photometry for an additional 400 million stars, and median radial velocities for about 7 million stars between magnitude 4 and 13. It also contains data for over 14,000 selected Solar System objects.[73][74] The coordinates in DR2 use the second Gaia celestial reference frame (Gaia–CRF2), which is based on observations of 492,006 sources believed to be quasars and has been described as "the first full-fledged optical realisation of the ICRS ... built only on extragalactic sources."[75] Comparison of the positions of 2,843 sources common to Gaia–CRF2 and a preliminary version of the ICRF3 shows a global agreement of 20 to 30 μas, although individual sources may differ by several mas.[76] Since the data processing procedure links individual Gaia observations with particular sources on the sky, in some cases the association of observations with sources will be different in the second data release. Consequently, DR2 uses different source identification numbers than DR1.[77] A number of issues have been identified with the DR2 data, including small systematic errors in astrometry and significant contamination of radial velocity values in crowded star fields, which may affect some one percent of the radial velocity values. Ongoing work should resolve these issues in future releases.[78] A guide for researchers using Gaia DR2, which collected "all information, tips and tricks, pitfalls, caveats and recommendations relevant to" DR2, was prepared by the Gaia Helpdesk in December 2019.[72]

 
Stars and other objects in Gaia Early Data Release 3

Due to uncertainties in the data pipeline, the third data release, based on 34 months of observations, has been split into two parts so that data that was ready first, was released first. The first part, EDR3 ("Early Data Release 3"), consisting of improved positions, parallaxes and proper motions, was released on 3 December 2020.[79] The coordinates in EDR3 use a new version of the Gaia celestial reference frame (Gaia–CRF3), based on observations of 1,614,173 extragalactic sources,[79] 2,269 of which were common to radio sources in the third revision of the International Celestial Reference Frame (ICRF3).[80] Included is the Gaia Catalogue of Nearby Stars (GCNS), containing 331,312 stars within (nominally) 100 parsecs (330 light-years).[81][82]

DR3, on 13 June 2022, includes the EDR3 data plus Solar System data; variability information; results for non-single stars, for quasars, and for extended objects; astrophysical parameters; and a special data set, the Gaia Andromeda Photometric Survey (GAPS), providing a photometric time series for about 1 million sources located in a 5.5-degree radius field centered on the Andromeda galaxy.[83][84] The release dates of EDR3 and DR3 were delayed by the effects of the COVID-19 pandemic on the Gaia Data Processing and Analysis Consortium.[85][86]

Future releases

The full data release for the five-year nominal mission, DR4, will include full astrometric, photometric and radial-velocity catalogues, variable-star and non-single-star solutions, source classifications plus multiple astrophysical parameters for stars, unresolved binaries, galaxies and quasars, an exo-planet list and epoch and transit data for all sources. Additional release(s) will take place depending on mission extensions.[64] Most measurements in DR4 are expected to be 1.7 times more precise than DR2; proper motions will be 4.5 times more precise.[87]

The last catalogue DR5, assuming an additional two-year extension until late-2024, will use and publish the full ten years of data. It will be 1.4 times more precise than DR4, while proper motions will be 2.8 times more precise than DR4.[87] It will be published not earlier than three years after the end of the mission. All data of all catalogues will be available in an online data base that is free to use.

An outreach application, Gaia Sky, has been developed to explore the galaxy in three dimensions using Gaia data.[88]

Significant results

In July 2017 the Gaia-ESO Survey reported using the data to find double-, triple-, and quadruple- stars. Using advanced techniques they identified 342 binary candidates, 11 triple candidates, and 1 quadruple candidate. Nine of these had been identified by other means, thus confirming that the technique can correctly identify multiple star systems.[89] The possible quadruple star system is HD 74438, which was, in a paper published in 2022, identified as a possible progenitor of a sub-Chandrasekhar Type Ia supernovae.[90]

In November 2017, scientists led by Davide Massari of the Kapteyn Astronomical Institute, University of Groningen, Netherlands released a paper[91] describing the characterization of proper motion (3D) within the Sculptor dwarf galaxy, and of that galaxy's trajectory through space and with respect to the Milky Way, using data from Gaia and the Hubble Space Telescope. Massari said, "With the precision achieved we can measure the yearly motion of a star on the sky which corresponds to less than the size of a pinhead on the Moon as seen from Earth." The data showed that Sculptor orbits the Milky Way in a highly elliptical orbit; it is currently near its closest approach at a distance of about 83.4 kiloparsecs (272,000 ly), but the orbit can take it out to around 222 kiloparsecs (720,000 ly) distant.

In October 2018, Leiden University astronomers were able to determine the orbits of 20 hypervelocity stars from the DR2 dataset. Expecting to find a single star exiting the Milky Way, they instead found seven. More surprisingly, the team found that 13 hypervelocity stars were instead approaching the Milky Way, possibly originating from as-of-yet unknown extragalactic sources. Alternatively, they could be halo stars to this galaxy, and further spectroscopic studies will help determine which scenario is more likely.[92][93] Independent measurements have demonstrated that the greatest Gaia radial velocity among the hypervelocity stars is contaminated by light from nearby bright stars in a crowded field and cast doubt on the high Gaia radial velocities of other hypervelocity stars.[94]

In late October 2018, the galactic population Gaia-Enceladus, the remains of a major merger with the defunct Enceladus dwarf, was discovered.[95] This system is associated with at least 13 globular clusters, and the creation of the Thick Disk of the Milky Way. It represents a significant merger about 10 billion years ago in the Milky Way Galaxy.[96]

 
Gaia's HR Diagram

In November 2018, the galaxy Antlia 2 was discovered. It is similar in size to the Large Magellanic Cloud, despite being 10,000 times fainter. Antlia 2 has the lowest surface brightness of any galaxy discovered.[97]

In December 2019 the star cluster Price-Whelan 1 was discovered.[98] The cluster belongs to the Magellanic Clouds and is located in the leading arm of these Dwarf Galaxies. The discovery suggests that the stream of gas extending from the Magellanic Clouds to the Milky Way is about half as far from the Milky Way as previously thought.[99]

The Radcliffe wave was discovered in data measured by Gaia, published in January 2020.[100][101]

In November 2020, Gaia measured the acceleration of the solar system towards the galactic center as 0.23 nanometers/s2.[102][103]

In March 2021, the European Space Agency announced that Gaia had identified a transiting exoplanet for the first time. The planet was discovered orbiting solar-type star Gaia EDR3 3026325426682637824. Following its initial discovery, the PEPSI spectrograph from the Large Binocular Telescope (LBT) in Arizona was used to confirm the discovery and categorise it as a Jovian planet, a gas planet composed of hydrogen and helium gas.[104][105] In May 2022, the confirmation of this exoplanet, designated Gaia-1b, was formally published, along with a second planet, Gaia-2b.[106]

Based on its data, Gaia's Hertzsprung-Russell diagram (HR diagram) is one of the most accurate ones ever produced of the Milky Way Galaxy.[107]

GaiaNIR

GaiaNIR (Gaia Near Infra-Red) is a proposed successor of Gaia in the near-infrared. The mission could enlarge the current catalog with sources that are only visible in the near-infrared and at the same time improve the star parallax and proper motion accuracy by revisiting the sources of the Gaia catalog.[108] One of the main challenges in building GaiaNIR is the low technology readiness level of near-infrared time delay and integration detectors. In a 2017 ESA report two alternative concepts using conventional near-infrared detectors and de-spin mirrors were proposed but even without the development of NIR TDI detectors the technological challenge will likely increase the cost over an ESA M-class mission and might need shared cost with other space agencies.[108] One possible partnership with US institutions was proposed.[109]

Gallery

  •  

    Four maps of the galaxy: radial velocity (top left), proper motion (bottom left); interstellar dust (top right); and metallicity (bottom right).[110]

  •  

    A visualisation of Gaia scanning the sky in great circles lasting about 6 hours from July 2014 to September 2015.[111]

  •  

    Illustration of Oort's formulae describing the curve obtained from plotting angular velocities against the galactic longitude[112][113]

  •  

    Microlensing events over the galactic map as observed by Gaia from 2014 to 2018[114][115] (Timer on bottom left corner)

  •  

    The image covers about 0.6 square degrees, making it conceivable that there are some 2.8 million stars captured in this image sequence alone. The image appears in strips, each representing a sky mapper CCD. The image was taken on 7 February 2017.[118]

See also

References

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External links

 
Wikimedia Commons has media related to Gaia (spacecraft).
  • Gaia mission home
  • ESA Gaia mission
  • ESA Gaia Archive
  • Gaia page at ESA Spacecraft Operations
  • "Gaia blog". blogs.esa.int. European Space Agency.
  • Gaia library
  • Journey to a Billion Suns 30 January 2021 at the Wayback Machine is a 360° immersive film – Gaia mission.
  • Video (12:58) – 1st Data Release (Gaia; 14 September 2016) on YouTube
  • Video (03:47) – 2nd Data Release (Gaia; 25 April 2018) on YouTube
  • Video (01:25; 360° view) – Entire Sky (Gaia; 25 April 2018) on YouTube
  • GAIA article on eoPortal by ESA

January 13, 2023
gaia, spacecraft, gaia, space, observatory, european, space, agency, launched, 2013, expected, operate, until, 2025, spacecraft, designed, astrometry, measuring, positions, distances, motions, stars, with, unprecedented, precision, mission, aims, construct, la. Gaia is a space observatory of the European Space Agency ESA launched in 2013 and expected to operate until 2025 The spacecraft is designed for astrometry measuring the positions distances and motions of stars with unprecedented precision 5 6 The mission aims to construct by far the largest and most precise 3D space catalog ever made totalling approximately 1 billion astronomical objects mainly stars but also planets comets asteroids and quasars among others 7 GaiaArtist s impression of the Gaia spacecraftMission typeAstrometric observatoryOperatorESACOSPAR ID2013 074ASATCAT no 39479Websitesci wbr esa wbr int wbr gaia wbr Mission duration9 years and 24 days in progress Spacecraft propertiesManufacturerEADS Astrium e2v TechnologiesLaunch mass2 029 kg 4 473 lb 1 Dry mass1 392 kg 3 069 lb Payload mass710 kg 1 570 lb 2 Dimensions4 6 m 2 3 m 15 1 ft 7 5 ft Power1 910 wattsStart of missionLaunch date19 December 2013 09 12 14 UTC 2013 12 19UTC09 12 14Z 3 RocketSoyuz ST B Fregat MTLaunch siteKourou ELSContractorArianespaceOrbital parametersReference systemSun Earth L2RegimeLissajous orbitPeriapsis altitude263 000 km 163 000 mi 4 Apoapsis altitude707 000 km 439 000 mi 4 Period180 daysEpoch2014Main telescopeTypeThree mirror anastigmat 1 Diameter1 45 m 0 5 m 4 ft 9 in 1 ft 8 in Collecting area0 7 m2TranspondersBandS Band TT amp C support X Band data acquisition Bandwidtha few kbit s down amp up S Band 3 8 Mbit s download X Band InstrumentsASTRO Astrometric instrument BP RP Photometric instrument RVS Radial velocity spectrometerESA astrophysics insignia for Gaia Horizon 2000 Plus PlanckLISA Pathfinder To study the precise position and motion of its target objects the spacecraft monitored each of them about 70 times 8 over the five years of the nominal mission 2014 2019 and continues to do so during its extension 9 10 The spacecraft has enough micro propulsion fuel to operate until about November 2024 11 As its detectors are not degrading as fast as initially expected the mission could therefore be extended 12 Gaia targets objects brighter than magnitude 20 in a broad photometric band that covers the extended visual range between near UV and near infrared 13 such objects represent approximately 1 of the Milky Way population 8 Additionally Gaia is expected to detect thousands to tens of thousands of Jupiter sized exoplanets beyond the Solar System by using the astrometry method 14 15 500 000 quasars outside this galaxy and tens of thousands of known and new asteroids and comets within the Solar System 16 17 18 The Gaia mission will create a precise three dimensional map of astronomical objects throughout the Milky Way and map their motions which encode the origin and subsequent evolution of the Milky Way The spectrophotometric measurements will provide the detailed physical properties of all stars observed characterizing their luminosity effective temperature gravity and elemental composition This massive stellar census will provide the basic observational data to analyze a wide range of important questions related to the origin structure and evolutionary history of the Milky Way galaxy The successor to the Hipparcos mission operational 1989 1993 Gaia is part of ESA s Horizon 2000 long term scientific program Gaia was launched on 19 December 2013 by Arianespace using a Soyuz ST B Fregat MT rocket flying from Kourou in French Guiana 19 20 The spacecraft currently operates in a Lissajous orbit around the Sun Earth L2 Lagrangian point Contents 1 History 2 Objectives 3 Spacecraft 3 1 Scientific instruments 3 2 Measurement principles 4 Data processing 5 Launch and orbit 6 Stray light problem 7 Mission progress 7 1 Data releases 7 2 Future releases 7 3 Significant results 8 GaiaNIR 9 Gallery 10 See also 11 References 12 External linksHistory EditThe Gaia space telescope has its roots in ESA s Hipparcos mission 1989 1993 Its mission was proposed in October 1993 by Lennart Lindegren Lund Observatory Lund University Sweden and Michael Perryman ESA in response to a call for proposals for ESA s Horizon Plus long term scientific programme It was adopted by ESA s Science Programme Committee as cornerstone mission number 6 on 13 October 2000 and the B2 phase of the project was authorised on 9 February 2006 with EADS Astrium taking responsibility for the hardware The name Gaia was originally derived as an acronym for Global Astrometric Interferometer for Astrophysics This reflected the optical technique of interferometry that was originally planned for use on the spacecraft While the working method evolved during studies and the acronym is no longer applicable the name Gaia remained to provide continuity with the project 21 The total cost of the mission is around 740 million 1 billion including the manufacture launch and ground operations 22 Gaia was completed two years behind schedule and 16 above its initial budget mostly due to the difficulties encountered in polishing Gaia s ten silicon carbide mirrors and assembling and testing the focal plane camera system 23 Objectives EditThe Gaia space mission has the following objectives To determine the intrinsic luminosity of a star requires knowledge of its distance One of the few ways to achieve this without physical assumptions is through the star s parallax but atmospheric effects and instrumental biases degrade the precision of parallax measurements For instance Cepheid variables are used as standard candles to measure distances to galaxies but their own distances are poorly known Thus quantities depending on them such as the speed of expansion of the universe remain inaccurate Measuring their distances accurately has a great impact on the understanding of the other galaxies and thus the whole cosmos see cosmic distance ladder Observations of the faintest objects will provide a more complete view of the stellar luminosity function Gaia will observe 1 billion stars and other bodies representing 1 of such bodies in the Milky Way galaxy 23 All objects up to a certain magnitude must be measured in order to have unbiased samples To permit a better understanding of the more rapid stages of stellar evolution such as the classification frequency correlations and directly observed attributes of rare fundamental changes and of cyclical changes This has to be achieved by detailed examination and re examination of a great number of objects over a long period of operation Observing a large number of objects in the galaxy is also important to understand the dynamics of this galaxy Measuring the astrometric and kinematic properties of a star is necessary in order to understand the various stellar populations especially the most distant In order to achieve these objectives Gaia has these goals Determine the position parallax and annual proper motion of 1 billion stars with an accuracy of about 20 microarcseconds mas at 15 mag and 200 mas at 20 mag Determine the positions of stars at a magnitude of V 10 down to a precision of 7 mas this is equivalent to measuring the position to within the diameter of a hair from 1000 km away between 12 and 25 mas down to V 15 and between 100 and 300 mas to V 20 depending on the colour of the star The distance to about 20 million stars will thus be measured with a precision of 1 or better and about 200 million distances will be measured to better than 10 Distances accurate to 10 will be achieved as far away as the Galactic Center 30 000 light years away 24 Measure the tangential speed of 40 million stars to a precision of better than 0 5 km s Derive the atmospheric parameters effective temperature line of sight interstellar extinction surface gravity metallicity for all stars observed 25 plus some more detailed chemical abundances for targets brighter than V 15 26 Measure the orbits and inclinations of a thousand extrasolar planets accurately determining their true mass using astrometric planet detection methods 27 28 More precisely measure the bending of starlight by the Sun s gravitational field predicted by Albert Einstein s General Theory of Relativity and first detected by Arthur Eddington during a 1919 solar eclipse and therefore directly observe the structure of spacetime 21 Potential to discover Apohele asteroids with orbits that lie between Earth and the Sun a region that is difficult for Earth based telescopes to monitor since this region is only visible in the sky during or near the daytime 29 Detect up to 500 000 quasars Spacecraft Edit Model of Gaia at Paris Air Show 2013 Gaia at its final phase of construction 2013 Gaia was launched by Arianespace using a Soyuz ST B rocket with a Fregat MT upper stage from the Ensemble de Lancement Soyouz at Kourou in French Guiana on 19 December 2013 at 09 12 UTC 06 12 local time The satellite separated from the rocket s upper stage 43 minutes after launch at 09 54 UTC 30 31 The craft headed towards the Sun Earth Lagrange point L2 located approximately 1 5 million kilometres from Earth arriving there 8 January 2014 32 The L2 point provides the spacecraft with a very stable gravitational and thermal environment There it uses a Lissajous orbit that avoids blockage of the Sun by the Earth which would limit the amount of solar energy the satellite could produce through its solar panels as well as disturb the spacecraft s thermal equilibrium After launch a 10 metre diameter sunshade was deployed The sunshade always faces the Sun thus keeping all telescope components cool and powering Gaia using solar panels on its surface Scientific instruments Edit The Gaia payload consists of three main instruments The astrometry instrument Astro precisely determines the positions of all stars brighter than magnitude 20 by measuring their angular position 13 By combining the measurements of any given star over the five year mission it will be possible to determine its parallax and therefore its distance and its proper motion the velocity of the star projected on the plane of the sky The photometric instrument BP RP allows the acquisition of luminosity measurements of stars over the 320 1000 nm spectral band of all stars brighter than magnitude 20 13 The blue and red photometers BP RP are used to determine stellar properties such as temperature mass age and elemental composition 21 33 Multi colour photometry is provided by two low resolution fused silica prisms dispersing all the light entering the field of view in the along scan direction prior to detection The Blue Photometer BP operates in the wavelength range 330 680 nm the Red Photometer RP covers the wavelength range 640 1050 nm 34 The Radial Velocity Spectrometer RVS is used to determine the velocity of celestial objects along the line of sight by acquiring high resolution spectra in the spectral band 847 874 nm field lines of calcium ion for objects up to magnitude 17 Radial velocities are measured with a precision between 1 km s V 11 5 and 30 km s V 17 5 The measurements of radial velocities are important to correct for perspective acceleration which is induced by the motion along the line of sight 34 The RVS reveals the velocity of the star along the line of sight of Gaia by measuring the Doppler shift of absorption lines in a high resolution spectrum In order to maintain the fine pointing to focus on stars many light years away the only moving parts are actuators to align the mirrors and the valves to fire the thrusters It has no reaction wheels or gyroscopes The spacecraft subsystems are mounted on a rigid silicon carbide frame which provides a stable structure that will not expand or contract due to temperature Attitude control is provided by small cold gas thrusters that can output 1 5 micrograms of nitrogen per second The telemetric link with the satellite is about 3 Mbit s on average while the total content of the focal plane represents several Gbit s Therefore only a few dozen pixels around each object can be downlinked Diagram of Gaia Mirrors M Mirrors of telescope 1 M1 M2 and M3 Mirrors of telescope 2 M 1 M 2 and M 3 mirrors M4 M 4 M5 M6 are not shownOther components 1 9 Optical bench silicon carbide torus Focal plane cooling radiator Focal plane electronics 35 Nitrogen tanks Diffraction grating spectroscope Liquid propellant tanks Star trackers Telecommunication panel and batteries Main propulsion subsystem A Light path of telescope 1 Design of the focal plane and instruments The design of the Gaia focal plane and instruments Due to the spacecraft s rotation images cross the focal plane array right to left at 60 arcseconds per second 35 Incoming light from mirror M3 Incoming light from mirror M 3 Focal plane containing the detector for the Astrometric instrument in light blue Blue Photometer in dark blue Red Photometer in red and Radial Velocity Spectrometer in pink Mirrors M4 and M 4 which combine the two incoming beams of light Mirror M5 Mirror M6 which illuminates the focal plane Optics and diffraction grating for the Radial Velocity Spectrometer RVS Prisms for the Blue Photometer and Red Photometer BP and RP Measurement principles Edit Comparison of nominal sizes of apertures of the Gaia spacecraft and some notable optical telescopes Scanning method Similar to its predecessor Hipparcos but with a precision one hundred times better Gaia consists of two telescopes providing two observing directions with a fixed wide angle of 106 5 between them 36 The spacecraft rotates continuously around an axis perpendicular to the two telescopes lines of sight The spin axis in turn has a slight precession across the sky while maintaining the same angle to the Sun By precisely measuring the relative positions of objects from both observing directions a rigid system of reference is obtained The two key telescope properties are 1 45 0 5 m primary mirror for each telescope 1 0 0 5 m focal plane array on which light from both telescopes is projected This in turn consists of 106 CCDs of 4500 1966 pixels each for a total of 937 8 megapixels commonly depicted as a gigapixel class imaging device 37 38 39 Each celestial object was observed on average about 70 times during the five years of the nominal mission which has been extended to approximately ten years and will thus obtain twice as many observations 40 These measurements will help determine the astrometric parameters of stars two corresponding to the angular position of a given star on the sky two for the derivatives of the star s position over time motion and lastly the star s parallax from which distance can be calculated The radial velocity of the brighter stars is measured by an integrated spectrometer observing the Doppler effect Because of the physical constraints imposed by the Soyuz spacecraft Gaia s focal arrays could not be equipped with optimal radiation shielding and ESA expected their performance to suffer somewhat toward the end of the initial five year mission Ground tests of the CCDs while they were subjected to radiation provided reassurance that the primary mission s objectives can be met 41 The expected accuracies of the final catalogue data have been calculated following in orbit testing taking into account the issues of stray light degradation of the optics and the basic angle instability The best accuracies for parallax position and proper motion are obtained for the brighter observed stars apparent magnitudes 3 12 The standard deviation for these stars is expected to be 6 7 micro arcseconds or better For fainter stars error levels increase reaching 26 6 micro arcseconds error in the parallax for 15th magnitude stars and several hundred micro arcseconds for 20th magnitude stars 42 For comparison the best parallax error levels from the new Hipparcos reduction are no better than 100 micro arcseconds with typical levels several times larger 43 Data processing Edit VST snaps Gaia en route to a billion stars 44 The overall data volume that was retrieved from the spacecraft during the nominal five year mission at a compressed data rate of 1 Mbit s is approximately 60 TB amounting to about 200 TB of usable uncompressed data on the ground stored in an InterSystems Cache database The responsibility of the data processing partly funded by ESA is entrusted to a European consortium the Data Processing and Analysis Consortium DPAC which was selected after its proposal to the ESA Announcement of Opportunity released in November 2006 DPAC s funding is provided by the participating countries and has been secured until the production of Gaia s final catalogue 45 Gaia sends back data for about eight hours every day at about 5 Mbit s ESA s three 35 metre diameter radio dishes of the ESTRACK network in Cebreros Spain Malargue Argentina and New Norcia Australia receive the data 21 Launch and orbit EditAnimation of Gaia s trajectory Polar view Equatorial view Viewed from the Sun Gaia Earth Simplified illustration of Gaia s trajectory and orbit not to scale In October 2013 ESA had to postpone Gaia s original launch date due to a precautionary replacement of two of Gaia s transponders These are used to generate timing signals for the downlink of science data A problem with an identical transponder on a satellite already in orbit motivated their replacement and reverification once incorporated into Gaia The rescheduled launch window was from 17 December 2013 to 5 January 2014 with Gaia slated for launch on 19 December 46 Gaia was successfully launched on 19 December 2013 at 09 12 UTC 47 About three weeks after launch on 8 January 2014 it reached its designated orbit around the Sun Earth L2 Lagrange point SEL2 4 48 about 1 5 million kilometers from Earth In 2015 the Pan STARRS observatory discovered an object orbiting the Earth which the Minor Planet Center catalogued as object 2015 HP116 It was soon found to be an accidental rediscovery of the Gaia spacecraft and the designation was promptly retracted 49 Stray light problem EditShortly after launch ESA revealed that Gaia was suffering from a stray light problem The problem was initially thought to be due to ice deposits causing some of the light diffracted around the edges of the sunshield and entering the telescope apertures to be reflected towards the focal plane 50 The actual source of the stray light was later identified as the fibers of the sunshield protruding beyond the edges of the shield 51 This results in a degradation in science performance which will be relatively modest and mostly restricted to the faintest of Gaia s one billion stars Mitigation schemes are being implemented 52 to improve performance The degradation is more severe for the RVS spectrograph than for the astrometry measurements because it spreads the light of the star onto a much larger number of detector pixels which each collect scattered light This kind of problem has some historical background In 1985 on STS 51 F the Space Shuttle Spacelab 2 mission another astronomical mission hampered by stray debris was the Infrared Telescope IRT in which a piece of mylar insulation broke loose and floated into the line of sight of the telescope causing corrupted data 53 The testing of stray light and baffles is a noted part of space imaging instruments 54 Mission progress Edit Gaia map of the sky by star density The testing and calibration phase which started while Gaia was en route to SEL2 point continued until the end of July 2014 55 three months behind schedule due to unforeseen issues with stray light entering the detector After the six month commissioning period the satellite started its nominal five year period of scientific operations on 25 July 2014 using a special scanning mode that intensively scanned the region near the ecliptic poles on 21 August 2014 Gaia began using its normal scanning mode which provides more uniform coverage 56 Although it was originally planned to limit Gaia s observations to stars fainter than magnitude 5 7 tests carried out during the commissioning phase indicated that Gaia could autonomously identify stars as bright as magnitude 3 When Gaia entered regular scientific operations in July 2014 it was configured to routinely process stars in the magnitude range 3 20 57 Beyond that limit special procedures are used to download raw scanning data for the remaining 230 stars brighter than magnitude 3 methods to reduce and analyse these data are being developed and it is expected that there will be complete sky coverage at the bright end with standard errors of a few dozen mas 58 In 2018 the Gaia mission was extended to 2020 In 2020 the Gaia mission was further extended through 2022 with an additional indicative extension extending through 2025 59 60 The limiting factor to further mission extensions is the supply of nitrogen for the cold gas thrusters of the micro propulsion system which is expected to last until November 2024 11 The amount of dinitrogen tetroxide NTO and monomethylhydrazine MMH for the chemical propulsion subsystem on board might be enough to stabilize the spacecraft at L2 for several decades Without the cold gas the space craft can no longer be pointed on a microarcsecond scale On 12 September 2014 Gaia discovered its first supernova in another galaxy 61 On 3 July 2015 a map of the Milky Way by star density was released based on data from the spacecraft 62 As of August 2016 more than 50 billion focal plane transits 110 billion photometric observations and 9 4 billion spectroscopic observations have been successfully processed 63 Data releases Edit Main article Gaia catalogues Several Gaia catalogues are released over the years each time with increasing amounts of information and better astrometry the early releases also miss some stars especially fainter stars located in dense star fields and members of close binary pairs 64 The first data release Gaia DR1 based on only 14 months of observation was on 14 September 2016 65 66 and is described in Astronomy and Astrophysics 67 The data release includes positions and magnitudes for 1 1 billion stars using only Gaia data positions parallaxes and proper motions for more than 2 million stars based on a combination of Gaia and Tycho 2 data for those objects in both catalogues light curves and characteristics for about 3 000 variable stars and positions and magnitudes for more than 2000 extragalactic sources used to define the celestial reference frame 64 68 69 Data from this DR1 release can be accessed at the Gaia archive 70 as well as through astronomical data centers such as CDS The second data release DR2 which occurred on 25 April 2018 7 71 is based on 22 months of observations made between 25 July 2014 and 23 May 2016 It includes positions parallaxes and proper motions for about 1 3 billion stars and positions of an additional 300 million stars in the magnitude range g 3 20 72 red and blue photometric data for about 1 1 billion stars and single colour photometry for an additional 400 million stars and median radial velocities for about 7 million stars between magnitude 4 and 13 It also contains data for over 14 000 selected Solar System objects 73 74 The coordinates in DR2 use the second Gaia celestial reference frame Gaia CRF2 which is based on observations of 492 006 sources believed to be quasars and has been described as the first full fledged optical realisation of the ICRS built only on extragalactic sources 75 Comparison of the positions of 2 843 sources common to Gaia CRF2 and a preliminary version of the ICRF3 shows a global agreement of 20 to 30 mas although individual sources may differ by several mas 76 Since the data processing procedure links individual Gaia observations with particular sources on the sky in some cases the association of observations with sources will be different in the second data release Consequently DR2 uses different source identification numbers than DR1 77 A number of issues have been identified with the DR2 data including small systematic errors in astrometry and significant contamination of radial velocity values in crowded star fields which may affect some one percent of the radial velocity values Ongoing work should resolve these issues in future releases 78 A guide for researchers using Gaia DR2 which collected all information tips and tricks pitfalls caveats and recommendations relevant to DR2 was prepared by the Gaia Helpdesk in December 2019 72 Stars and other objects in Gaia Early Data Release 3Due to uncertainties in the data pipeline the third data release based on 34 months of observations has been split into two parts so that data that was ready first was released first The first part EDR3 Early Data Release 3 consisting of improved positions parallaxes and proper motions was released on 3 December 2020 79 The coordinates in EDR3 use a new version of the Gaia celestial reference frame Gaia CRF3 based on observations of 1 614 173 extragalactic sources 79 2 269 of which were common to radio sources in the third revision of the International Celestial Reference Frame ICRF3 80 Included is the Gaia Catalogue of Nearby Stars GCNS containing 331 312 stars within nominally 100 parsecs 330 light years 81 82 DR3 on 13 June 2022 includes the EDR3 data plus Solar System data variability information results for non single stars for quasars and for extended objects astrophysical parameters and a special data set the Gaia Andromeda Photometric Survey GAPS providing a photometric time series for about 1 million sources located in a 5 5 degree radius field centered on the Andromeda galaxy 83 84 The release dates of EDR3 and DR3 were delayed by the effects of the COVID 19 pandemic on the Gaia Data Processing and Analysis Consortium 85 86 Future releases Edit The full data release for the five year nominal mission DR4 will include full astrometric photometric and radial velocity catalogues variable star and non single star solutions source classifications plus multiple astrophysical parameters for stars unresolved binaries galaxies and quasars an exo planet list and epoch and transit data for all sources Additional release s will take place depending on mission extensions 64 Most measurements in DR4 are expected to be 1 7 times more precise than DR2 proper motions will be 4 5 times more precise 87 The last catalogue DR5 assuming an additional two year extension until late 2024 will use and publish the full ten years of data It will be 1 4 times more precise than DR4 while proper motions will be 2 8 times more precise than DR4 87 It will be published not earlier than three years after the end of the mission All data of all catalogues will be available in an online data base that is free to use An outreach application Gaia Sky has been developed to explore the galaxy in three dimensions using Gaia data 88 Significant results Edit In July 2017 the Gaia ESO Survey reported using the data to find double triple and quadruple stars Using advanced techniques they identified 342 binary candidates 11 triple candidates and 1 quadruple candidate Nine of these had been identified by other means thus confirming that the technique can correctly identify multiple star systems 89 The possible quadruple star system is HD 74438 which was in a paper published in 2022 identified as a possible progenitor of a sub Chandrasekhar Type Ia supernovae 90 In November 2017 scientists led by Davide Massari of the Kapteyn Astronomical Institute University of Groningen Netherlands released a paper 91 describing the characterization of proper motion 3D within the Sculptor dwarf galaxy and of that galaxy s trajectory through space and with respect to the Milky Way using data from Gaia and the Hubble Space Telescope Massari said With the precision achieved we can measure the yearly motion of a star on the sky which corresponds to less than the size of a pinhead on the Moon as seen from Earth The data showed that Sculptor orbits the Milky Way in a highly elliptical orbit it is currently near its closest approach at a distance of about 83 4 kiloparsecs 272 000 ly but the orbit can take it out to around 222 kiloparsecs 720 000 ly distant In October 2018 Leiden University astronomers were able to determine the orbits of 20 hypervelocity stars from the DR2 dataset Expecting to find a single star exiting the Milky Way they instead found seven More surprisingly the team found that 13 hypervelocity stars were instead approaching the Milky Way possibly originating from as of yet unknown extragalactic sources Alternatively they could be halo stars to this galaxy and further spectroscopic studies will help determine which scenario is more likely 92 93 Independent measurements have demonstrated that the greatest Gaia radial velocity among the hypervelocity stars is contaminated by light from nearby bright stars in a crowded field and cast doubt on the high Gaia radial velocities of other hypervelocity stars 94 In late October 2018 the galactic population Gaia Enceladus the remains of a major merger with the defunct Enceladus dwarf was discovered 95 This system is associated with at least 13 globular clusters and the creation of the Thick Disk of the Milky Way It represents a significant merger about 10 billion years ago in the Milky Way Galaxy 96 Gaia s HR Diagram In November 2018 the galaxy Antlia 2 was discovered It is similar in size to the Large Magellanic Cloud despite being 10 000 times fainter Antlia 2 has the lowest surface brightness of any galaxy discovered 97 In December 2019 the star cluster Price Whelan 1 was discovered 98 The cluster belongs to the Magellanic Clouds and is located in the leading arm of these Dwarf Galaxies The discovery suggests that the stream of gas extending from the Magellanic Clouds to the Milky Way is about half as far from the Milky Way as previously thought 99 The Radcliffe wave was discovered in data measured by Gaia published in January 2020 100 101 In November 2020 Gaia measured the acceleration of the solar system towards the galactic center as 0 23 nanometers s2 102 103 In March 2021 the European Space Agency announced that Gaia had identified a transiting exoplanet for the first time The planet was discovered orbiting solar type star Gaia EDR3 3026325426682637824 Following its initial discovery the PEPSI spectrograph from the Large Binocular Telescope LBT in Arizona was used to confirm the discovery and categorise it as a Jovian planet a gas planet composed of hydrogen and helium gas 104 105 In May 2022 the confirmation of this exoplanet designated Gaia 1b was formally published along with a second planet Gaia 2b 106 Based on its data Gaia s Hertzsprung Russell diagram HR diagram is one of the most accurate ones ever produced of the Milky Way Galaxy 107 GaiaNIR EditGaiaNIR Gaia Near Infra Red is a proposed successor of Gaia in the near infrared The mission could enlarge the current catalog with sources that are only visible in the near infrared and at the same time improve the star parallax and proper motion accuracy by revisiting the sources of the Gaia catalog 108 One of the main challenges in building GaiaNIR is the low technology readiness level of near infrared time delay and integration detectors In a 2017 ESA report two alternative concepts using conventional near infrared detectors and de spin mirrors were proposed but even without the development of NIR TDI detectors the technological challenge will likely increase the cost over an ESA M class mission and might need shared cost with other space agencies 108 One possible partnership with US institutions was proposed 109 Gallery Edit Four maps of the galaxy radial velocity top left proper motion bottom left interstellar dust top right and metallicity bottom right 110 A visualisation of Gaia scanning the sky in great circles lasting about 6 hours from July 2014 to September 2015 111 Illustration of Oort s formulae describing the curve obtained from plotting angular velocities against the galactic longitude 112 113 Microlensing events over the galactic map as observed by Gaia from 2014 to 2018 114 115 Timer on bottom left corner The image covers about 0 6 square degrees making it conceivable that there are some 2 8 million stars captured in this image sequence alone The image appears in strips each representing a sky mapper CCD The image was taken on 7 February 2017 118 See also EditGaia Archive Gaia Catalogue Cosmic distance ladder Succession of methods by which astronomers determine the distances to celestial objects SIM PlanetQuest a cancelled US projectReferences Edit a b GAIA Global Astrometric Interferometer for Astrophysics Mission ESA eoPortal Retrieved 28 March 2014 Frequently Asked Questions about Gaia ESA 14 November 2013 Gaia Liftoff ESA 19 December 2013 a b c Gaia enters its operational orbit ESA 8 January 2014 ESA Gaia home ESA Retrieved 23 October 2013 Spie 2014 Timo Prusti plenary Gaia Scientific In orbit Performance SPIE Newsroom doi 10 1117 2 3201407 13 a b Overbye Dennis 1 May 2018 Gaia s Map of 1 3 Billion Stars Makes for a Milky Way in a Bottle The New York Times Retrieved 1 May 2018 a b ESA Gaia spacecraft summary ESA 20 May 2011 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Delchambre L Ducourant C Teixeira R Surdej J Boehm C den Brok J Dobie D 28 October 2021 Gaia GraL Gaia DR2 Gravitational Lens Systems VI Spectroscopic Confirmation and Modeling of Quadruply Imaged Lensed Quasars The Astrophysical Journal 921 1 42 arXiv 2012 10051 Bibcode 2021ApJ 921 42S doi 10 3847 1538 4357 ac0f04 ISSN 0004 637X S2CID 229331628 Gaia sky mapper image near the Galactic centre www esa int Retrieved 19 September 2022 External links Edit Wikimedia Commons has media related to Gaia spacecraft Gaia mission home ESA Gaia mission ESA Gaia Archive Gaia page at ESA Spacecraft Operations Gaia blog blogs esa int European Space Agency Gaia library Journey to a Billion Suns Archived 30 January 2021 at the Wayback Machine is a 360 immersive film Gaia mission Video 12 58 1st Data Release Gaia 14 September 2016 on YouTube Video 03 47 2nd Data Release Gaia 25 April 2018 on YouTube Video 01 25 360 view Entire Sky Gaia 25 April 2018 on YouTube GAIA article on eoPortal by ESA Portals Astronomy Stars Spaceflight Solar System Science Retrieved from https en wikipedia org w index php title Gaia spacecraft amp oldid 1133182980, wikipedia, wiki, book, books, library,

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