Q: Matias, how did you get involved in ESO’s hunt for exoplanets?

A: I first became interested in the field of exoplanets during my PhD at the Universidad de Chile in Santiago, Chile. This was back in 2008 when I started to search for planets around giant stars. These kinds of stars are near the end of their lives, so they expand to have large radii and cool into red giants. This stellar expansion phase may greatly affect the architecture of planetary systems. The orbital angular momentum transferred from the planet to the star, created by the mutual attraction between the planet and the stellar surface, causes the planet to slow down and move into an inner orbit until it is evaporated by the heat from the stellar surface. By looking for close-in planets (or lack of them) orbiting such evolved stars, we can measure how efficiently planets are destroyed by this mechanism.

During my PhD, I was able to spend two years in the ESO studentship programme in Vitacura. Afterwards, I got a postdoctoral position at the Astro Engineering Center of La Pontificia Universidad Católica de Chile, also in Santiago, where I worked mainly on extrasolar planet searches. I also helped to develop a high-resolution spectrograph, called FIDEOS (FIber Dual Echelle Optical Spectrograph), optimised to search for exoplanets using the radial velocity method. This spectrograph is currently installed at ESO’s La Silla Observatory. At the end of 2016, I started a fellowship at ESO in Vitacura and Paranal.

ESO telescopes can detect stars wobble due to the gravitational pull of (unseen) exoplanets. When the star moves towards us, its light is blueshifted, while it becomes redshifted when moving away from us.

Credit: ESO

This composite image shows an exoplanet (the red spot on the lower left) orbiting the brown dwarf 2M1207 (centre). 2M1207b is the first exoplanet directly imaged and the first discovered orbiting a brown dwarf. It was imaged the first time by the VLT in 2004 with the NACO adaptive-optics facility.

Credit: ESO

Using ESO’s SPHERE instrument at the Very Large Telescope, a team of astronomers observed the planetary disc surrounding the star HD 135344B, about 450 light-years away. The disc shows prominent spiral-arm-like structures. These are thought to have been created by one or more massive protoplanets, destined to become Jupiter-like worlds. The central part of the image appears dark because SPHERE blocks out the light from the brilliant central star to reveal the much fainter structures surrounding it.

Credit: ESO, T. Stolker et al.

Q: How are exoplanets detected? Can we look for them in images or do we have to observe the parent star?

A: Many methods have been developed to detect extrasolar planets, but there are three main methods:

Firstly, the radial velocity method: As a planet orbits a star, they exert a gravitational force on each other. The star’s force is huge and the planet’s force is tiny, but it is enough to make the star wobble slightly. We can look for either a blueshift (as the star moves towards us) or a redshift (as the star moves away) in the star’s light, and thus infer its radial velocity. From these measurements, we can figure out may different things about the planet, such as its orbital period, minimum mass, and so on. With current ESO instruments, we can measure the velocity of the star with a precision of less than a metre per second.

Secondly, the transit method: If the planetary orbit is aligned with the line of sight of the observer, then the planet blocks a portion of the stellar light when the planet passes in front of the parent star. If we periodically measure this tiny decrease in light, we can infer that this effect is caused by an unseen companion as it orbits and then infer information such as the planet’s radius. This is, like the previous method, an indirect detection.

This method is particularly interesting for studying planetary atmospheres. As the light from the star passes through the atmosphere on its way to Earth, the atmosphere absorbs some of this light. Different elements absorb light with different wavelengths (colours) and so by studying this light you can see which molecules are in the atmosphere of the planet. Then you can start searching for specific molecules, especially the ones that are biomarkers, that could be evidence of life.

Thirdly, direct imaging: This is the only technique that directly takes an image of exoplanets. To look for planetary companions, we use adaptive optics, to compensate for the atmospheric turbulence, and a coronagraph that blocks the light from the star. However, this method is mainly restricted to relatively massive, young sub-stellar companions because these planets are more luminous than lighter and older planets, making their detection possible.

Q: How does ESO search for exoplanets?

A: Several ESO instruments are optimised for hunting exoplanets. Perhaps the most prolific one is HARPS (the High Accuracy Radial velocity Planet Searcher), which is a high-resolution spectrograph attached to the ESO 3.6-metre telescope on La Silla. HARPS leads the field of ground-based exoplanet hunting, and it’s one of the most successful planet finders in the history of astronomy. It uses the radial velocity method, picking up the slight wobbles of a star with amazing precision.

Another high-resolution spectrograph, ESPRESSO (Echelle SPectrograph for Rocky Exoplanet and Stable Spectroscopic Observations), has just come online at the Very Large Telescope (VLT). It’s basically the successor to HARPS but on a much bigger telescope, so it will take the search for exoplanets to the next level.

We also have instruments that can directly image exoplanets, such as the adaptive-optics instruments NACO and SPHERE, both on different Unit Telescopes (UTs) at Paranal. NACO took the first-ever direct image of an exoplanet back in 2004. SPHERE focuses on finding new giant exoplanets orbiting nearby stars, and can also look at discs of dust and debris around other stars, where planets may be forming.

Q: What are some of the biggest exoplanet breakthroughs and discoveries made by ESO so far?

A: There are many interesting discoveries made with ESO instruments. For instance, using HARPS astronomers have detected hundreds of planetary systems, including the famous TRAPPIST-1 system just 40 light-years from Earth. This system has both the largest number of Earth-sized planets yet found and the largest number of worlds that could support liquid water on their surfaces.

An artist’s impression compares the seven planets orbiting the ultra-cool red dwarf star TRAPPIST-1 to the Earth at the same scale.

Credit: ESO/M. Kornmesser

HARPS also discovered a rocky planet, Proxima Centauri b, orbiting the closest star to our Sun. Intriguingly it has a temperature suitable for liquid water to exist on its surface.

Additionally, instruments like NACO and SPHERE have allowed us to detect a few massive substellar companions, like gas giants several times more massive than Jupiter, using the direct imaging technique, plus many protoplanetary discs, where we think most planets form.

This artist’s impression shows a view of the surface of the planet Proxima b orbiting the red dwarf star Proxima Centauri, the closest star to the Solar System. This planet was discovered using the HARPS spectrograph on the ESO 3.6-metre telescope at La Silla in Chile.

Credit: ESO/M. Kornmesser

Q: Will the upcoming ELT change what ESO can learn about alien worlds?

A: The Extremely Large Telescope will be equipped with incredibly advanced instruments that will allow us to detect exoplanets in a more efficient way. The ELT may hopefully discover more exoplanets like radial velocity and direct imaging, and, with the latter technique, may even be able to study these planetary atmospheres. For these techniques, the size of the telescope really matters, so the ELT will play a huge role. It will be revolutionary. The ELT will also allow us to study planetary systems as they’re still forming, helping us answer fundamental questions about how planets form and evolve.

But we don’t have to wait for the ELT to improve our knowledge of exoplanets. There are also always new instruments coming to telescopes at La Silla and Paranal, and continuous upgrades of the current facilities improve the science output of the current instruments. In particular, near-infrared spectrographs will allow us to detect and study exoplanets in more detail — for instance, to study their atmosphere.

Q: What excites you most about exoplanet science, both now and in the future?

A: I'm interested in several aspects of exoplanets, but particularly in their long-term stability of exoplanets and the period of time when a parent star engulfs a planet as it evolves into a red giant. By studying other planetary systems, we can gain some information about our own Solar System when the Sun becomes a giant star about five billion years from now. For instance, we now know that short-period planets around giant stars are rare compared to solar-type stars. This might be at least in part due to the tidal destruction of the innermost planets by stars expanding as they age. By combining transit data from the Kepler mission with radial velocity measurements, we have already been able to detect a few such close-in planets, which we expect will be engulfed “soon” by their parent stars.

An artist’s rendering showing the Extremely Large Telescope in operation on Cerro Armazones in northern Chile. The telescope will be equipped with incredibly advanced instruments that will help us answer fundamental questions about how planets form and evolve.

Credit: ESO/L. Calçada

Q: You work up on the mountain at Paranal — what’s it like to spend so much time in such an amazing environment?

A: ESO Fellows in Santiago basically spend half of their time at the ESO offices in Vitacura doing research, and half of the time doing functional work for the observatory, mainly as a support astronomer. I spend about 80 days per year up on the mountain, providing support for visiting astronomers and operating the instruments that I am assigned (SPHERE and VISIR mounted on UT3). When no visiting astronomer is present at the telescope to collect their own data, we perform the observations in “service mode.” In this mode, we decide which observations are done during the night in collaboration with the telescope operators.

I really enjoy my time on Paranal for two main reasons. First of all, the environment is fantastic — it is really a unique place. Paranal is located in the middle of the driest desert in the world and at an altitude of 2635 metres. The view at sunset and sunrise is simply amazing. All of the mountains reflect the sunlight and become very nice reddish colours. At night, especially when there is no Moon, the view of the Milky Way is astonishing.

From a more scientific perspective, the VLT at Paranal is the most advanced optical observatory in the world — not only because of the large aperture telescopes, each 8.2 metres in diameter, but also because of the instruments that are attached to them. These instruments deliver very high-quality data, allowing us to do front-line research in astronomy. For me, it is a unique opportunity to work in such a great environment.

Sunset at Paranal, the most advanced optical observatory in the world and the workplace of ESO Fellow Matias Jones.

Credit: ESO/B. Tafreshi (twanight.org)