Skip to main content

Astronomers use new method to discover planet orbiting two stars

Astronomers using NASA’s Transiting Exoplanet Survey Satellite (TESS) telescope have used a new detection technique to discover an unusual planet that orbits two stars. The planet TIC 172900988b has two suns, making it a type of planet called a circumbinary, and it is the first of its kind to be detected using TESS observing just two transits.

Exoplanets, or planets outside our solar system, are usually too small and faint to be seen directly. But astronomers can infer their existence using a variety of techniques including transits. A transit is an event when an exoplanet passes between Earth and its host star, temporarily blocking out some of the star’s light. Astronomers look for these drops in light and use them to predict the presence of a planet.

Illustration of TIC 172900988b, a planet orbiting two stars.
Illustration of TIC 172900988b, a planet orbiting two stars. Dr. Pamela Gay / Planetary Science Institute

However, this is more difficult when a planet orbits two stars, as one of the researchers who discovered this planet, Planetary Science Institute Senior Scientist Nader Haghighipour, explained in a statement:

“Detecting circumbinary planets is much more complicated than detecting planets orbiting single stars,” Haghighiour said. “The most promising technique for detecting circumbinary planets is transit photometry, which measures drops in starlight caused by those planets whose orbits are oriented in space such that they periodically pass between their stars and the telescope. In this technique, the measurements of the decrease in the intensity of the light of a star is used to infer the existence of a planet.

“To determine the orbit of the planet, precisely, at least three transit events are required. This becomes complicated when a planet orbits a double-star system because transits will not happen with same interval over the same star. The planet may transit one star and then transit the other before transiting the first star again, and so on.”

A newly discovered planet was observed in the system TIC 172900988.
A newly discovered planet was observed in the system TIC 172900988. In TESS data, it passed in front of the primary star (right), and 5 days later (shown) passed in front of the second star (left). These stars are just over 30% larger than the Sun and differ very little in size. Dr. Pamela Gay / Planetary Science Institute

The problem is that detecting three transits can take a very long time — and TESS only looks at a given portion of the sky for 27 days, which is usually too little time to see three transits. But in the case of TIC 172900988b, a planet roughly the size of Jupiter, the team was able to detect it using just two transits — one transit of each of its host stars.

The authors are hopeful that this new technique means telescopes like TESS will be able to discover more circumbinary planets in the future.

The research is published in The Astronomical Journal.

Georgina Torbet
Georgina is the Digital Trends space writer, covering human space exploration, planetary science, and cosmology. She…
Astronomers spot rare star system with six planets in geometric formation
Orbital geometry of HD110067: Tracing a link between two neighbour planets at regular time intervals along their orbits, creates a pattern unique to each couple. The six planets of the HD110067 system together create a mesmerising geometric pattern due to their resonance-chain.

Astronomers have discovered a rare star system in which six planets orbit around one star in an elaborate geometrical pattern due to a phenomenon called orbital resonance. Using both NASA's Transiting Exoplanet Survey Satellite (TESS) and the European Space Agency's (ESA) CHaracterising ExOPlanet Satellite (CHEOPS), the researchers have built up a picture of the beautiful, but complex HD110067 system, located 100 light-years away.

The six planets of the system orbit in a pattern whereby one planet completes three orbits while another does two, and one completes six orbits while another does one, and another does four orbits while another does three, and so one. The six planets form what is called a "resonant chain" where each is in resonance with the planets next to it.

Read more
How astronomers used James Webb to detect methane in the atmosphere of an exoplanet
An artists rendering of a blue and white exoplanet known as WASP-80 b, set on a star-studded black background. Alternating horizontal layers of cloudy white, grey and blue cover the planets surface. To the right of the planet, a rendering of the chemical methane is depicted with four hydrogen atoms bonded to a central carbon atom, representing methane within the exoplanet's atmosphere. An artist’s rendering of the warm exoplanet WASP-80 b whose color may appear bluish to human eyes due to the lack of high-altitude clouds and the presence of atmospheric methane identified by NASA’s James Webb Space Telescope, similar to the planets Uranus and Neptune in our own solar system.

One of the amazing abilities of the James Webb Space Telescope is not just detecting the presence of far-off planets, but also being able to peer into their atmospheres to see what they are composed of. With previous telescopes, this was extremely difficult to do because they lacked the powerful instruments needed for this kind of analysis, but scientists using Webb recently announced they had made a rare detection of methane in an exoplanet atmosphere.

Scientists studied the planet WASP-80 b using Webb's NIRCam instrument, which is best known as a camera but also has a slitless spectroscopy mode which allows it to split incoming light into different wavelengths. By looking at which wavelengths are missing because they have been absorbed by the target, researchers can tell what an object -- in this case, a planetary atmosphere -- is composed of.

Read more
Astronomers discover how tiny dwarf galaxies form ‘fossils’
A dwarf galaxy in the throes of transitioning to an ultra-compact dwarf galaxy as it’s stripped of its outer layers of stars and gas by a nearby larger galaxy.

Galaxies come in many different shapes and sizes, including those considerably smaller than our Milky Way. These smaller galaxies, called dwarf galaxies, can have as few as 1,000 stars, compared to the several hundred billion in our galaxy. And when these dwarf galaxies age and begin to erode away, they can transform into an even smaller and more dense shape, called an ultra-compact dwarf galaxy.

The Gemini North telescope has recently been studying more than 100 of these eroding dwarf galaxies, seeing how they lose their outer stars and gas to become ultra-compact dwarf galaxies or UCDs.

Read more