Stardust study resets how life’s atoms spread

“We thought we had a good idea of how the process worked. It turns out we were wrong. For us as scientists, that’s the most exciting result”, says Theo Khouri, astronomer at Chalmers and joint leader of the study.

To understand the origins of life on Earth, it’s important for astronomers to understand how giant stars power their winds. Red giant stars seed the galaxy with carbon, oxygen, nitrogen and other elements essential for life. For decades, scientists have believed that winds from red giant stars are powered when starlight pushes against grains of newly formed dust. The new observations of R Doradus challenge this picture. 

Combined knowledge

Gunnar Nyman, professor of physical chemistry at the University of Gothenburg is part of the team.

“To try to understand this star, we’ve combined knowledge from astronomy, physics and chemistry, using what we know about the star itself, the gas surrounding it, and the atoms and molecules that make up grains of stardust”, he says.

Red giant stars are the older, cooler cousins of the Sun. As they age, they lose large amounts of material through stellar winds, enriching the space between stars with the raw ingredients for future planets and life. Despite their importance, the physical mechanism driving these winds has remained uncertain.

Stardust too small

Astronomers studying the nearby red giant star R Doradus have found that the tiny grains of stardust surrounding the star are too small to be pushed outward by starlight strongly enough to escape into interstellar space. 

“Using the world’s best telescopes, we can now make detailed observations of the closest giant stars. R Doradus is a favourite target of ours – it’s bright, nearby, and typical of the most common type of red giant”, says Theo Khouri. “

The team observed R Doradus, measuring light reflected by dust grains in a region roughly the size of our Solar System. By analysing polarised light at different wavelengths, the researchers determined the size and composition of the grains, finding them consistent with common forms of stardust such as silicates and alumina.

The observations were then combined with advanced computer simulations that model how starlight interacts with dust.

“For the first time, we were able to carry out stringent tests of whether these dust grains can feel a strong enough push from the star’s light”, says Thiébaut Schirmer.

Rising bubbles

The push of starlight is not enough; the team was surprised to find. The grains surrounding R Doradus are typically only about one ten-thousandth of a millimetre across — far too small for starlight alone to drive the star’s wind into space.

“Dust is definitely present, and it is illuminated by the star,” says Thiébaut Schirmer. “But it simply doesn’t provide enough force to explain what we see.”

The findings point to other, more complex processes playing a major role. The team has previously used the ALMA telescope to capture images of enormous bubbles rising and falling on the surface of R Doradus.

“Even though the simplest explanation doesn’t work, there are exciting alternatives to explore,” says Wouter Vlemmings, professor at Chalmers and co-author of the study. “Giant convective bubbles, stellar pulsations, or dramatic episodes of dust formation could all help explain how these winds are launched.”

The study in Astronomy & Astrophysics: “An empirical view of the extended atmosphere and inner envelope of the asymptotic giant branch star R Doradus II. Constraining the dust properties with radiative transfer modelling”

Contact info: Theo Khouri, astronomer, Chalmers University of Technology, theo.khouri@chalmers.se

Gunnar Nyman, Professor i physical chemistry at the University of Gothenburg, phone: 031-786 90 35, email: gunnar.nyman@gu.se