Skip to main content
  1. Home
  2. Space
  3. News

This oddball pair of stars is producing dust shells like clockwork

By

The James Webb Space Telescope has spotted an intriguing object created by a rare pair of stars that are encircled by rings of dust. The pair, known as Wolf-Rayet 140, is located 5,000 light-years away and could us learn about the interstellar medium between stars and how stars form.

This system consists of two stars, one older and massive of a type called a Wolf-Rayet star, and the other hot a blue-white type called an O-type star. And they orbit in such a way that they come close together once every eight years. When that happens, the stellar winds that each star gives off begin to interact. This interaction causes the large Wolf-Rayet star to shed some of its stellar material, which forms dust.

Shells of cosmic dust created by the interaction of binary stars appear like tree rings around Wolf-Rayet 140.
Shells of cosmic dust created by the interaction of binary stars appear like tree rings around Wolf-Rayet 140. The remarkable regularity of the shells’ spacing indicates that they form like clockwork during the stars’ eight-year orbit cycle, when the two members of the binary make their closest approach to one another. In this image, blue, green, and red were assigned to Webb’s Mid-Infrared Instrument (MIRI) data at 7.7, 15, and 21 microns (F770W, F1500W, and F2100W filters, respectively). NASA, ESA, CSA, STScI, NASA-JPL, Caltech

It is this formation of dust every eight years which creates the dust shells seen in the image above. Each interaction creates a new shell, and at least 17 of these shells are visible in the Webb data, showing over 130 years of history between the two stars.

Recommended Videos

“We’re looking at over a century of dust production from this system,” said lead author Ryan Lau, an astronomer at NSF’s NOIRLab, in a statement. “The image also illustrates just how sensitive this telescope is. Before, we were only able to see two dust rings, using ground-based telescopes. Now we see at least 17 of them.”

Webb was able to see the many shells using its Mid-Infrared instrument, which allowed the researchers to use different filters to see the chemical composition of the dust shells. They found they are made of compounds called Polycyclic Aromatic Hydrocarbons (PAHs), which are found in the space between stars — called the interstellar medium — and which play an important role in how stars form. There are only around 600 Wolf-Rayet stars known, but there could be evidence of many more in our galaxy.

“Even though Wolf-Rayet stars are rare in our galaxy because they are short-lived as far as stars go, it’s possible they’ve been producing lots of dust throughout the history of the galaxy before they explode and/or form black holes,” said co-author Patrick Morris of Caltech. “I think with NASA’s new space telescope we’re going to learn a lot more about how these stars shape the material between stars and trigger new star formation in galaxies.”

The research is published in the journal Nature Astronomy.

Editors’ Recommendations

Topics
Georgina Torbet
Georgina Torbet
Space Writer
Georgina is the Digital Trends space writer, covering human space exploration, planetary science, and cosmology. She…
James Webb captures the edge of the beautiful Horsehead Nebula
The NASA/ESA/CSA James Webb Space Telescope has captured the sharpest infrared images to date of one of the most distinctive objects in our skies, the Horsehead Nebula. These observations show a part of the iconic nebula in a whole new light, capturing its complexity with unprecedented spatial resolution. Webb’s new images show part of the sky in the constellation Orion (The Hunter), in the western side of the Orion B molecular cloud. Rising from turbulent waves of dust and gas is the Horsehead Nebula, otherwise known as Barnard 33, which resides roughly 1300 light-years away.

A new image from the James Webb Space Telescope shows the sharpest infrared view to date of a portion of the famous Horsehead Nebula, an iconic cloud of dust and gas that's also known as Barnard 33 and is located around 1,300 light-years away.

The Horsehead Nebula is part of a large cloud of molecular gas called Orion B, which is a busy star-forming region where many young stars are being born. This nebula  formed from a collapsing cloud of material that is illuminated by a bright, hot star located nearby. The image shows the very top part of the nebula, catching the section that forms the "horse's mane."

Read more
James Webb images capture the galactic winds of newborn stars
A team of astronomers used the NASA/ESA/CSA James Webb Space Telescope to survey the starburst galaxy Messier 82 (M82), which is located 12 million light-years away in the constellation Ursa Major. M82 hosts a frenzy of star formation, sprouting new stars 10 times faster than the Milky Way galaxy. Webb’s infrared capabilities enabled scientists to peer through curtains of dust and gas that have historically obscured the star formation process. This image from Webb’s NIRCam (Near-Infrared Camera) instrument shows the centre of M82 with an unprecedented level of detail. With Webb’s resolution, astronomers can distinguish small, bright compact sources that are either individual stars or star clusters. Obtaining an accurate count of the stars and clusters that compose M82’s centre can help astronomers understand the different phases of star formation and the timelines for each stage.

A stunning new pair of images from the James Webb Space Telescope show a new view of a familiar galaxy. Messier 82 is a famous starburst galaxy, full of bright and active star formation, and scientists are using Webb to study how stars are being born in the busy conditions at the center of the galaxy.

Astronomers used Webb's NIRCam instrument to observe the galaxy, and by splitting the resulting data into shorter and longer wavelengths, you can see different features which are picked out in the bustling, active region where stars are forming.

Read more
The expansion rate of the universe still has scientists baffled
This image of NGC 5468, a galaxy located about 130 million light-years from Earth, combines data from the Hubble and James Webb space telescopes. This is the most distant galaxy in which Hubble has identified Cepheid variable stars. These are important milepost markers for measuring the expansion rate of the Universe. The distance calculated from Cepheids has been cross-correlated with a Type Ia supernova in the galaxy. Type Ia supernovae are so bright they are used to measure cosmic distances far beyond the range of the Cepheids, extending measurements of the Universe’s expansion rate deeper into space.

The question of how fast the universe is expanding continues to confound scientists. Although it might seem like a fairly straightforward issue, the reality is that it has been perplexing the best minds in physics and astronomy for decades -- and new research using the James Webb Space Telescope and the Hubble Space Telescope doesn't make the answer any clearer.

Scientists know that the universe is expanding over time, but what they can't agree on is the rate at which this is happening -- called the Hubble constant. There are two main methods used to estimate this constant: one that looks at how fast distant galaxies are moving away from us, and one that looks at leftover energy from the Big Bang called the cosmic microwave background. The trouble is, these two methods give different results.

Read more