Stars need a buddy to make gamma-ray bursts

Artist’s impression of gamma-ray burst with orbiting binary star. (Credit: Mark Garlick/ U. Warwick)

When it comes to the biggest and brightest explosions seen in the universe, it takes two stars to make a gamma-ray burst, astronomers report.

The new research solves the mystery of how stars spin fast enough to create conditions to launch a jet of highly energetic material into space: tidal effects like those between the moon and Earth are the answer.

Researchers made the discovery, reported in Monthly Notices of the Royal Astronomical Society, using simulated models of thousands of binary star systems, that is, solar systems that have two stars orbiting one another.

More than half of all stars are located in binary star systems—and the new study shows they need to be in binary star systems to create the massive explosions.

Won’t you be my neighbor?

A long gamma-ray burst (GRB) occurs when a massive star about 10 times the size of our sun goes supernova, collapses into a neutron star or black hole, and fires a relativistic jet of material into space.

Instead of the star collapsing radially inwards, it flattens down into a disc to conserve angular momentum. As the material falls inwards, that angular momentum launches it in the form of a jet along the polar axis.

But in order to form that jet of material, the star has to be spinning fast enough to launch material along the axis. This presents a problem because stars usually lose any spin they acquire very quickly. Modeling behavior of these massive stars as they collapse, allowed researchers to constrain the factors that cause a jet to form.

They found that the effects of tides from a close neighbor—the same effect that has the moon and Earth locked together in their spin—could be responsible for spinning these stars at the rate needed to create a gamma-ray burst.

Spinning stars

Gamma-ray bursts, the most luminous events in the universe, are observable from Earth when their jet of material points directly at us. This means that we only see around 10-20% of the GRBs in the skies.

“We’re predicting what kind of stars or systems produce gamma-ray bursts, which are the biggest explosions in the universe. Until now it’s been unclear what kind of stars or binary systems you need to produce that result,” says lead author Ashley Chrimes, a PhD student in the physics department at the University of Warwick.

“The question has been how a star starts spinning, or maintains its spin over time. We found that the effect of a star’s tides on its partner is stopping them from slowing down and, in some cases, it is spinning them up. They are stealing rotational energy from their companion, a consequence of which is that they then drift further away.

“What we have determined is that the majority of stars are spinning fast precisely because they’re in a binary system.”

Ideal conditions for gamma ray bursts

The study uses a collection of binary stellar evolution models researchers from the University of Warwick and JJ Eldridge from the University of Auckland created. Using a technique called binary population synthesis, the scientists can simulate this mechanism in a population of thousands of star systems and identify the rare examples where an explosion of this type can occur.

“Scientists haven’t modeled in detail for binary evolution in the past because it’s a very complex calculation to do,” says Elizabeth Stanway from the physics department. “This work has considered a physical mechanism within those models that we haven’t examined before, that suggests that binaries can produce enough GRBs using this method to explain the number that we are observing.

“There has also been a big dilemma over the metallicity of stars that produce gamma-ray bursts. As astronomers, we measure the composition of stars and the dominant pathway for gamma-ray bursts requires very few iron atoms or other heavy elements in the stellar atmosphere. There’s been a puzzle over why we see a variety of compositions in the stars producing gamma-ray bursts, and this model offers an explanation.”

Chrimes adds: “This model allows us to predict what these systems should look like observationally in terms of their temperature and luminosity, and what the properties of the companion are likely to be. We are now interested in applying this analysis to explore different astrophysical transients, such as fast radio bursts, and can potentially model rarer events such as black holes spiraling into stars.”

The Science and Technology Facilities Council funded the work.

Source: University of Warwick