First Giant Exoplanet Planet Found Around White Dwarf Star [Video]

Artist's Impression of WDJ0914+1914

This illustration shows the white dwarf WDJ0914+1914 and its Neptune-like exoplanet. Since the icy giant orbits the hot white dwarf at close range, the extreme ultraviolet radiation from the star strips away the planet’s atmosphere. While most of this stripped gas escapes, some of it swirls into a disc, itself accreting onto the white dwarf. Credit: ESO/M. Kornmesser

ESO observations indicate the Neptune-like exoplanet is evaporating.

Researchers using ESO’s Very Large Telescope have, for the first time, found evidence of a giant exoplanet associated with a white dwarf star. The planet orbits the hot white dwarf, the remnant of a Sun-like star, at close range, causing its atmosphere to be stripped away and form a disc of gas around the star. This unique system hints at what our own Solar System might look like in the distant future.

“It was one of those chance discoveries,” says researcher Boris Gänsicke, from the University of Warwick in the UK, who led the study, published today in the journal Nature. The team had inspected around 7,000 white dwarfs observed by the Sloan Digital Sky Survey and found one to be unlike any other. By analyzing subtle variations in the light from the star, they found traces of chemical elements in amounts that scientists had never before observed at a white dwarf. “We knew that there had to be something exceptional going on in this system, and speculated that it may be related to some type of planetary remnant.”


Researchers using ESO’s Very Large Telescope have, for the first time, found evidence of a giant planet associated with a white dwarf star. The planet orbits the hot white dwarf, the remnant of a Sun-like star, at close range, causing its atmosphere to be stripped away and form a disc of gas around the star. Credit: ESO

To get a better idea of the properties of this unusual star, named WDJ0914+1914, the team analyzed it with the X-shooter instrument on ESO’s Very Large Telescope in the Chilean Atacama Desert. These follow-up observations confirmed the presence of hydrogen, oxygen, and sulfur associated with the white dwarf. By studying the fine details in the spectra taken by ESO’s X-shooter, the team discovered that these elements were in a disc of gas swirling into the white dwarf, and not coming from the star itself.

Location of WDJ0914+1914 in the constellation of Cancer

This chart shows the location of WDJ0914+1914 in the constellation of Cancer (The Crab). This map shows most of the stars visible to the unaided eye under good conditions, and WDJ0914+1914 itself is highlighted with a red circle on the image. This white dwarf is orbited by a Neptune-like exoplanet that is evaporating, the first ever giant planet found around a white dwarf. Credit: ESO, IAU and Sky & Telescope

“It took a few weeks of very hard thinking to figure out that the only way to make such a disc is the evaporation of a giant planet,” says Matthias Schreiber from the University of Valparaiso in Chile, who computed the past and future evolution of this system.

The detected amounts of hydrogen, oxygen, and sulfur are similar to those found in the deep atmospheric layers of icy, giant planets like Neptune and Uranus. If such a planet were orbiting close to a hot white dwarf, the extreme ultraviolet radiation from the star would strip away its outer layers and some of this stripped gas would swirl into a disc, itself accreting onto the white dwarf. This is what scientists think they are seeing around WDJ0914+1914: the first evaporating planet orbiting a white dwarf.

Combining observational data with theoretical models, the team of astronomers from the UK, Chile, and Germany were able to paint a clearer image of this unique system. The white dwarf is small and, at a blistering 28,000 degrees Celsius or 50,500 degrees Fahrenheit (five times the Sun’s temperature), extremely hot. By contrast, the planet is icy and large—at least twice as large as the star. Since it orbits the hot white dwarf at close range, making its way around it in just 10 days, the high-energy photons from the star are gradually blowing away the planet’s atmosphere. Most of the gas escapes, but some is pulled into a disc swirling into the star at a rate of 3000 tonnes per second. It is this disc that makes the otherwise hidden Neptune-like planet visible.


This animation shows the white dwarf WDJ0914+1914 and its Neptune-like exoplanet. Since the icy giant orbits the hot white dwarf at close range, the extreme ultraviolet radiation from the star strips away the planet’s atmosphere. While most of this stripped gas escapes, giving the planet a comet-like tail, some of it swirls into a disc, itself accreting onto the white dwarf. Credit: ESO/M. Kornmesser

“This is the first time we can measure the amounts of gases like oxygen and sulfur in the disc, which provides clues to the composition of exoplanet atmospheres,” says Odette Toloza from the University of Warwick, who developed a model for the disc of gas surrounding the white dwarf.

“The discovery also opens up a new window into the final fate of planetary systems,” adds Gänsicke.

Stars like our Sun burn hydrogen in their cores for most of their lives. Once they run out of this fuel, they puff up into red giants, becoming hundreds of times larger and engulfing nearby planets. In the case of the Solar System, this will include Mercury, Venus, and even Earth, which will all be consumed by the red-giant Sun in about 5 billion years. Eventually, Sun-like stars lose their outer layers, leaving behind only a burnt-out core, a white dwarf. Such stellar remnants can still host planets, and many of these star systems are thought to exist in our galaxy. However, until now, scientists had never found evidence of a surviving giant planet around a white dwarf. The detection of an exoplanet in orbit around WDJ0914+1914, located about 1500 light-years away in the constellation of Cancer, may be the first of many orbiting such stars.


Stars such as our Sun burn hydrogen in their cores for most of their lives. Once they run out of this fuel, they puff up into red giants, becoming hundreds of times larger and engulfing nearby planets. As shown in this animation, in the case of the Solar System this will include Mercury, Venus, and even Earth, which will all be consumed by the red-giant Sun in about 5 billion years.

Eventually, Sun-like stars lose their outer layers, leaving behind only a burnt-out core, a white dwarf. Such stellar remnants can still host planets, and many of these stars exist in our galaxy. However, until 2019, scientists had never found evidence of a surviving giant planet around a white dwarf. The detection of a Neptune-like exoplanet at WDJ0914+1914 may be the first of many orbiting such stars.

Credit: ESA/Hubble (M. Kornmesser & L. L. Christensen)

According to the researchers, the exoplanet now found with the help of ESO’s X-shooter orbits the white dwarf at a distance of only 10 million kilometers (6 million miles), or 15 times the solar radius, which would have been deep inside the red giant. The unusual position of the planet implies that at some point after the host star became a white dwarf, the planet moved closer to it. The astronomers believe that this new orbit could be the result of gravitational interactions with other planets in the system, meaning that more than one planet may have survived its host star’s violent transition.

“Until recently, very few astronomers paused to ponder the fate of planets orbiting dying stars. This discovery of a planet orbiting closely around a burnt-out stellar core forcefully demonstrates that the Universe is time and again challenging our minds to step beyond our established ideas,” concludes Gänsicke.

Read more about this discovery in Hidden Giant Planet Discovered Around Tiny White Dwarf Star.

Reference: “Accretion of a giant planet onto a white dwarf star” by Boris T. Gänsicke, Matthias R. Schreiber, Odette Toloza, Nicola P. Gentile Fusillo, Detlev Koester and Christopher J. Manser, 4 December 2019, Nature.
DOI: 10.1038/s41586-019-1789-8

The team is composed of Boris Gänsicke (Department of Physics & Center for Exoplanets and Habitability, University of Warwick, UK), Matthias Schreiber (Institute of Physics and Astronomy, Millennium Nucleus for Planet Formation, Valparaiso University, Chile), Odette Toloza (Department of Physics, University of Warwick, UK), Nicola Gentile Fusillo (Department of Physics, University of Warwick, UK), Detlev Koester (Institute for Theoretical Physics and Astrophysics, University of Kiel, Germany), and Christopher Manser (Department of Physics, University of Warwick, UK).

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