Echelle SPectrograph for Rocky Exoplanet and Stable Spectroscopic Observations

At the Very Large Telescope Interferometer under the VLT platform at ESO’s Paranal Observatory, engineers and astronomers worked against the clock to build new tunnels and rooms to house one of the most eagerly anticipated instruments in the astronomical world: ESPRESSO, or the Echelle SPectrograph for Rocky Exoplanet and Stable Spectroscopic Observations.

ESPRESSO is the successor to HARPS, one of most productive and precise planet hunters. With 97 papers in 2017 alone, HARPS has been much in demand by astronomers around the world, and has been the most productive instrument at the La Silla Observatory for several years. This is one of the reasons why astronomers were greatly looking forward to the arrival of ESPRESSO on a much bigger telescope.

The ESPRESSO spectrograph concept.
The ESPRESSO spectrograph concept.
MUSE colour-coded image of NGC 4650A
Engineering sample of one of the CCD detectors to be used in the cameras of the ESPRESSO instrument. These very large CCD samples were provided by the company e2v and have more than 80 million pixels over an area of 92 x 92 millimetres.
Credit: ESO/ESPRESSO Consortium/e2v

ESPRESSO can now take the search for exoplanets to the next level. It is fed by the four Unit Telescopes (UTs) of the VLT and its primary goal is to make very high precision radial velocity measurements of solar-type stars to search for rocky planets.

Stars and their exoplanets are bound together by gravity: an exoplanet orbits its distant parent star just as the planets of the Solar System orbit the Sun. But a planet in orbit around a star exerts its own gentle gravitational pull, so that the centre of gravity of the entire system (the barycentre) is a little away from the centre of the star and the star itself orbits about this point. This regular movement of the star along our line of sight creates a tiny shift in the spectrum of the star, through the Doppler effect. This minute effect can be detected by very sensitive instruments and is the evidence for the presence of a planet that can then be further studied. This tug of war between stars and their exoplanets can be seen (or rather, measured) by ESPRESSO.

ESPRESSO combines unprecedented radial velocity measurement accuracy with the large collecting area of the UTs. This means that we are able to gather light simultaneously from the 4 UTs and measure fainter objects in the sky with greater accuracy. HARPS has the precision to detect stellar motions moving at the speed of a gentle walking pace — 3.5 km/h! ESPRESSO is expected to be able to detect stellar motions at almost a snail’s pace — only 0.35 km/h — corresponding to an Earth-mass planet in the habitable zone of a low-mass star. It is expected that a vast number of planets with masses smaller than Neptune will be discovered.

The ESPRESSO instrument achieved first light with one of the VLT Unit Telescopes in December 2017 and first light with all four Unit Telescopes in February 2018.


The authoritative technical specifications as offered for astronomical observations are available from the Science Operations page.

Site: Paranal / Very Large Telescope
Telescope: VLT Combined-Coude Laboratory
Focus: Coude
Type: Spectrograph
Wavelength coverage: 380–686 nm
Spatial resolution: 3.5 pixels
Spectral resolution:  
First light date: February 2018
Images taken with the instrument: Link
Images of the instrument: Link
Press Releases with the instrument: Link
Data papers:


ESO data citation policy

Science goals:
  • The measurement of high precision radial velocities of solar type stars for search for rocky planets
  • The measurement of the variation of the physical constants
  • The analysis of the chemical composition of stars in nearby galaxies


  • Observatoire de Geneva and University of Bern, Switzerland
  • INAF-Trieste and Brera, Italy
  • Instituto de Astrofísica de Canarias, Spain
  • Universidade do Porto and Lisboa, Portugal
  • ESO