Violent star history: beautiful nebula and magnetic star born from a stellar clash

Violent star history: beautiful nebula and magnetic star born from a stellar clash


Brussels, 11 April 2024 – When astronomers looked at a stellar pair at the heart of a stunning cloud of gas and dust, they were in for a surprise. Star pairs are typically very similar, like twins, but in HD 148937, one star appears younger and, unlike the other, is magnetic. In a newly published Science research paper, scientists, including Laurent Mahy from the Royal Observatory of Belgium, suggest there were originally three stars in the system, until two of them clashed and merged. This violent event created the surrounding cloud and forever altered the system’s fate.

A Very Special Star System

‘When doing background reading, I was struck by how special this system seemed,’ says Abigail Frost, an astronomer at ESO in Chile and lead author of the study published today in Science. The system, HD 148937, is located about 3800 light years away from Earth in the direction of the Norma constellation. It is made up of two stars much more massive than the Sun and surrounded by a beautiful nebula, a cloud of gas and dust. ‘A nebula surrounding two massive stars is a rarity, and it really made us feel like something cool had to have happened in this system. When looking at the data, the coolness only increased.’

A blue bright star in space with an orange nebula cloud.

The nebula (NGC 6164/6165) surrounding HD 148937 as seen in visible light. This image, taken with the VLT Survey Telescope hosted at ESO’s Paranal Observatory, shows the beautiful nebula NGC 6164/6165, also known as the Dragon’s Egg. The nebula is a cloud of gas and dust surrounding a pair of stars called HD 148937. Credit: ESO/VPHAS+ team. Acknowledgement: CASU. Source: https://www.eso.org/public/images/eso2407a/?lang

‘After a detailed analysis, we could determine that the more massive star appears much younger than its companion, which doesn’t make any sense since they should have formed at the same time!’ Frost says. The age difference – one star appears to be at least 1.5 million years younger than the other – suggests something must have rejuvenated the more massive star.

Another piece of the puzzle is the nebula surrounding the stars, known as NGC 6164/6165. It is 7500 years old, hundreds of times younger than both stars. The nebula also shows very high amounts of nitrogen, carbon and oxygen. This is surprising as these elements are normally expected deep inside a star, not outside; it is as if some violent event had set them free.

Using ESO’s Data to Unravel the Mystery

To unravel the mystery, the team assembled nine years’ worth of data from the PIONIER and GRAVITY instruments, both on ESO’s Very Large Telescope Interferometer (VLTI), located in Chile’s Atacama Desert. They also used archival data from the FEROS instrument at ESO’s La Silla Observatory.

‘We think this system had at least three stars originally; two of them had to be close together at one point in the orbit whilst another star was much more distant,’ explains Hugues Sana, a professor at KU Leuven in Belgium and the principal investigator of the observations. ‘The two inner stars merged in a violent manner, creating a magnetic star and throwing out some material, which created the nebula. The more distant star formed a new orbit with the newly merged, now-magnetic star, creating the binary we see today at the centre of the nebula.’

Four image descriping the history of a three star system. From left to right, top to bottom : beginning with three stars; 2 stars merging, illustrating with a red light explosion; creation of a nebular resulting from the star clashing, the system HD 148937 now.

Artist’s impression: the violent history of stellar pair HD 148937. This collection of panels shows three artist’s impressions depicting the violent event that changed the fate of the stellar system HD 148937; a real astronomical image is shown in the last panel. Originally, the system had at least three stars (top left panel), two of them close together and another one much more distant, until one day the two inner stars clashed and merged (top right panel). This violent event created a new, larger and magnetic star, now in a pair with the more distant one (bottom left panel). The merger also released the materials that created the spectacular nebula now surrounding the stars (bottom right panel). Credit: ESO/L. Calçada, VPHAS+ team. Acknowledgement: CASU. Source: https://www.eso.org/public/images/eso2407b/?lang

In particular, Laurent Mahy, senior researcher at the Royal Observatory of Belgium, analysed the spectroscopic data of the system, to determine the surface parameters of the two individual components.

‘The merger scenario was already in my head back in 2017 when I studied nebula observations obtained with the European Space Agencys Herschel Space Telescope,’ adds Laurent Mahy of the Royal Observatory of Belgium. ‘Finding an age discrepancy between the stars suggests that this scenario is the most plausible one to produce such a beautiful nebula and it was only possible to show it with the new ESO data.’

This scenario also explains why one of the stars in the system is magnetic and the other is not – another peculiar feature of HD 148937 spotted in the VLTI data.

A galaxy in space with stars. The nebular NGC 6164/6165 is show in the middle, with a S-shaped nebula in orange.

Wide-field view of the region of the sky around the nebula NGC 6164/6165. This wide-field view, created from images forming part of the Digitized Sky Survey 2, shows the rich star clouds in the constellation of Norma (the Carpenter’s Square) in our Milky Way galaxy. The beautiful nebula NGC 6164/6165, also known as the Dragon’s Egg, appears in the centre of the image. Credit: ESO/Digitized Sky Survey 2. Acknowledgement: Davide De Martin. Source: “https://www.eso.org/public/images/eso2407c/?lang

How massive stars get their magnetic fields

At the same time, it helps solve a long-standing mystery in astronomy: how massive stars get their magnetic fields. While magnetic fields are a common feature of low-mass stars like our Sun, more massive stars cannot sustain magnetic fields in the same way. Yet some massive stars are indeed magnetic.

Astronomers had suspected for some time that massive stars could acquire magnetic fields when two stars merge. But this is the first time researchers find such direct evidence of this happening. In the case of HD 148937, the merger must have happened recently. ‘Magnetism in massive stars isn’t expected to last very long compared to the lifetime of the star, so it seems we have observed this rare event very soon after it happened,’ Frost adds.

The research has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement number 772225: MULTIPLES ; PI: Hugues Sana).

This communication is based on an ESO press release.

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