Telescopes Each Unit Telescope is a
Ritchey-Chretien Cassegrain telescope with a 22-tonne 8.2-metre
Zerodur primary mirror of 14.4-metre focal length, and a 1.1-metre lightweight beryllium secondary mirror. A flat tertiary mirror diverts the light to one of two instruments at the f/15
Nasmyth foci on either side, with a system focal length of 120 metres, or the tertiary tilts aside to allow light through the primary mirror central hole to a third instrument at the Cassegrain focus. This allows switching between any of the three instruments within five minutes, to match observing conditions. Additional mirrors can send the light via tunnels to the central VLTI beam-combiners. The maximum field-of-view (at Nasmyth foci) is around 27 arcminutes in diameter, slightly smaller than the full moon, though most instruments view a narrower field. Each telescope has an
alt-azimuth mount with total mass around 350 tonnes, and uses
active optics with 150 supports on the back of the primary mirror to control the shape of the thin (177 mm thick) mirror by computers. It has been decommissioned. ; CRIRES and CRIRES+ : The cryogenic infrared echelle spectrograph is an adaptive optics assisted
echelle spectrograph. It provides a resolving power of up to 100,000 in the infrared spectral range from 1 to 5 micrometres. From 2014 to 2020 it underwent a major upgrade to CRIRES+ to provide ten times larger simultaneous wavelength coverage. A new detector focal plane array of three Hawaii 2RG detectors with a 5.3 μm cut-off wavelength replaced the existing detectors, a new spectropolarimetric unit is added, and the calibration system is enhanced. One of the scientific objectives of CRIRES+ is in-transit
spectroscopy of exoplanets, which currently provides us with the only means of studying
exoplanetary atmospheres. Transiting planets are almost always close-in planets that are hot and radiate most of their light in the
infrared (IR). Furthermore, the IR is a spectral region where lines of
molecular gases like
carbon monoxide (CO),
ammonia (NH3), and
methane (CH4), etc. are expected from the exoplanetary
atmosphere. This important wavelength region is covered by CRIRES+, which will additionally allow tracking multiple
absorption lines simultaneously. ; ERIS : The enhanced resolution imager and spectrograph is the newest VLT instrument, which started science operation in 2023. It is an adaptive-optics assisted near-infrared imager (with coronagraph option) and integral-field spectrograph. It replaces the former NACO and SINFONI instruments with improved capability. ;
ESPRESSO : The echelle spectrograph for rocky exoplanet and stable spectroscopic observations is a high-resolution, fiber-fed and cross-dispersed echelle spectrograph for the visible wavelength range, capable of operating in 1-UT mode (using one of the four telescopes) and in 4-UT mode (using all four), for the search for rocky extra-solar planets in the habitable zone of their host stars. Its main feature is the spectroscopic stability and the radial-velocity precision. The requirement is to reach 10 cm/s, but the aimed goal is to obtain a precision level of few cm/s. ESPRESSO was installed and commissioned at the VLT in 2017–2018. ; FLAMES : The fibre large array multi-element spectrograph is a multi-object fibre feed unit for UVES and GIRAFFE, the latter allowing the capability for simultaneously studying hundreds of individual stars in nearby galaxies at moderate spectral resolution in the visible. ; FORS1/FORS2 : The focal reducer and low dispersion spectrograph is a visible light camera and Multi Object
Spectrograph with a 6.8 arcminute field of view. FORS2 is an upgraded version over FORS1 and includes further multi-object spectroscopy capabilities. FORS1 was retired in 2009 to make space for X-SHOOTER; FORS2 continues to operate as of 2021. ;
GRAVITY (VLTI) : GRAVITY is an adaptive optics assisted, near-infrared (NIR) instrument for micro-arcsecond precision narrow-angle astrometry and interferometric phase referenced imaging of faint celestial objects. This instrument interferometrically combines NIR light collected by four telescopes at the VLTI. ; HAWK-I : The high acuity wide field K-band imager is a near-infrared imager with a relatively large field of view, about 8x8 arcminutes. ; ISAAC : The infrared spectrometer and array camera was a near infrared imager and spectrograph; it operated successfully from 2000 to 2013 and was then retired to make way for SPHERE, since most of its capabilities can now be delivered by the newer HAWK-I or KMOS. ;
KMOS : KMOS (K-band Multi Object Spectrograph) is a cryogenic near-infrared multi-object spectrometer, observing 24 objects simultaneously, intended primarily for the study of distant galaxies. ; MATISSE (VLTI) : The multi aperture mid-infrared spectroscopic experiment is an infrared spectro-interferometer of the
VLT-Interferometer, which potentially combines the beams of all four Unit Telescopes (UTs) and four Auxiliary Telescopes (ATs). The instrument is used for image reconstruction. After 12 years of development It saw its first light at the telescope in Paranal in March 2018. ; MIDI (VLTI) : MIDI is an instrument combining two telescopes of the VLT in the mid-infrared, dispersing the light in a spectrograph to analyse the dust composition and shape of the observed object. MIDI is notably the second most-productive interferometric instrument ever (surpassed by
AMBER recently). MIDI was retired in March 2015 to prepare the VLTI for the arrival of GRAVITY and MATISSE. ;
MUSE : MUSE is a huge "3-dimensional" spectroscopic explorer which will provide complete visible spectra of all objects contained in "pencil beams" through the Universe. ; NACO : NAOS-CONICA, NAOS meaning Nasmyth adaptive optics system and CONICA, meaning Coude near infrared camera) is an
adaptive optics facility which produces infrared images as sharp as if taken in space and includes spectroscopic, polarimetric and coronagraphic capabilities. ;
PIONIER (VLTI) : Is an instrument to combine the light of all 8-metre telescopes, allowing to pick up details about 16 times finer than can be seen with one UT. ; SINFONI : The spectrograph for integral field observations in the near infrared) was a medium resolution,
near-infrared (1 to 2.5 micrometres) integral field spectrograph fed by an adaptive optics module. It operated from 2003, then retired in June 2019 to make space for the future ERIS. ;
SPHERE : The spectro-polarimetric high-contrast exoplanet research, a high-contrast adaptive optics system dedicated to the discovery and study of
exoplanets. ; ULTRACAM : ULTRACAM is a visitor instrument for ultra-high-speed photometry of variable objects. ULTRACAM provides three simultaneous bands of optical photometry. ; UVES : The ultraviolet and visual echelle spectrograph is a high-resolution
ultraviolet and visible light
echelle spectrograph. ;
VIMOS : The visible multi-object spectrograph delivered visible images and spectra of up to 1,000 galaxies at a time in a 14 × 14 arcmin field of view. It was mainly used for several large redshift surveys of distant galaxies, including VVDS, zCOSMOS and VIPERS. It was retired in 2018 to make space for the return of CRIRES+. ; VISIR : The VLT spectrometer and imager for the mid-infrared provides diffraction-limited imaging and spectroscopy at a range of resolutions in the 10 and 20 micrometre mid-infrared (MIR) atmospheric windows. VISIR hosts the NEAR science demonstration, where NEAR is new earths in the alpha centauri region. ; X-Shooter : X-Shooter is the first second-generation instrument, operating since 2009. It is a very wide-band [UV to near infrared] single-object spectrometer designed to explore the properties of rare, unusual or unidentified sources.
Interferometry (VLTI) with six baselines. In its
interferometric operating mode, the light from the telescopes is reflected off mirrors and directed through tunnels to a central beam combining laboratory. In the year 2001, during commissioning, the VLTI successfully measured the angular diameters of four red dwarfs including
Proxima Centauri. During this operation it achieved an angular resolution of ±0.08 milli-arc-seconds (0.388 nano-radians). This is comparable to the resolution achieved using other arrays such as the
Navy Prototype Optical Interferometer and the
CHARA array. Unlike many earlier optical and infrared interferometers, the
Astronomical Multi-Beam Recombiner (AMBER) instrument on VLTI was initially designed to perform coherent integration (which requires signal-to-noise greater than one in each atmospheric coherence time). Using the big telescopes and coherent integration, the faintest object the VLTI can observe is
magnitude 7 in the near infrared for broadband observations, similar to many
other near infrared / optical interferometers without fringe tracking. In 2011, an incoherent integration mode was introduced called AMBER "blind mode", which is more similar to the observation mode used at earlier interferometer arrays such as COAST, IOTA and CHARA. In this "blind mode", AMBER can observe sources as faint as K=10 in medium spectral resolution. At more challenging mid-infrared wavelengths, the VLTI can reach magnitude 4.5, significantly fainter than the
Infrared Spatial Interferometer. When fringe tracking is introduced, the limiting magnitude of the VLTI is expected to improve by a factor of almost 1000, reaching a magnitude of about 14. This is similar to what is expected for other fringe tracking interferometers. In spectroscopic mode, the VLTI can currently reach a magnitude of 1.5. The VLTI can work in a fully integrated way, so that interferometric observations are actually quite simple to prepare and execute. The VLTI has become worldwide the first general user optical/infrared interferometric facility offered with this kind of service to the astronomical community. train, the star separator, the main delay line, beam compressor and feeding optics. Additionally, the interferometric technique is such that it is very efficient only for objects that are small enough that all their light is concentrated. For instance, an object with a relatively low
surface brightness such as the moon cannot be observed, because its light is too diluted. Only targets which are at temperatures of more than have a
surface brightness high enough to be observed in the mid-infrared, and objects must be at several thousands of degrees Celsius for near-infrared observations using the VLTI. This includes most of the stars in the
solar neighborhood and many extragalactic objects such as bright
active galactic nuclei, but this sensitivity limit rules out
interferometric observations of most solar-system objects. Although the use of large telescope diameters and
adaptive optics correction can improve the sensitivity, this cannot extend the reach of optical interferometry beyond nearby stars and the brightest
active galactic nuclei. Because the Unit Telescopes are used most of the time independently, they are used in the interferometric mode mostly during bright time (that is, close to full moon). At other times,
interferometry is done using 1.8-metre Auxiliary Telescopes (ATs), which are dedicated to full-time interferometric measurements. The first observations using a pair of ATs were conducted in February 2005, and all the four ATs have now been commissioned. For interferometric observations on the brightest objects, there is little benefit in using 8 meter telescopes rather than 1.8-metre telescopes. The first two instruments at the VLTI were VINCI (a test instrument used to set up the system, now decommissioned) and MIDI, which only allow two telescopes to be used at any one time. With the installation of the three-telescope AMBER
closure-phase instrument in 2005, the first imaging observations from the VLTI are expected soon. Deployment of the Phase Referenced Imaging and Microarcsecond Astrometry (PRIMA) instrument started 2008 with the aim to allow phase-referenced measurements in either an astrometric two-beam mode or as a fringe-tracker successor to VINCI, operated concurrent with one of the other instruments. After falling drastically behind schedule and failing to meet some specifications, in December 2004 the VLT Interferometer became the target of a second
ESO "recovery plan". This involves additional effort concentrated on improvements to fringe tracking and the performance of the main
delay lines. Note that this only applies to the interferometer and not other instruments on Paranal. In 2005, the VLTI was routinely producing observations, although with a brighter limiting magnitude and poorer observing efficiency than expected. , the VLTI had already led to the publication of 89 peer-reviewed publications and had published a first-ever image of the inner structure of the mysterious
Eta Carinae. In March 2011, the
PIONIER instrument for the first time simultaneously combined the light of the four Unit Telescopes, potentially making VLTI the biggest optical telescope in the world. The first successful attempt was in February 2012, with four telescopes combined into a 130-metre diameter mirror. == Cancelled planned industrial complex ==