Ultracool dwarf binary stars break records
US astrophysicists have discovered the closest and oldest ultracool dwarf binary stars ever recorded
Northwestern University and the University of California San Diego (UC San Diego) astrophysicists have discovered the tightest ultracool dwarf binary system ever observed.
The two stars are so close that it takes them less than one Earth day to revolve around each other. In other words, each star’s ‘year’ lasts just 17 hours.
The newly discovered system, named LP 413-53AB, is composed of a pair of ultracool dwarfs, a class of very low-mass stars that are so cool that they emit their light primarily in the infrared, making them completely invisible to the human eye. They are nonetheless one of the most common types of stars in the universe.
Previously, astronomers had only detected three short-period ultracool dwarf binary systems, all of which are relatively young; up to 40 million years old. LP 413-53AB is estimated to be billions of years old – similar age to our sun – but has an orbital period that is at least three times shorter than the all the ultracool dwarf binaries discovered so far.
Chih-Chun ‘Dino’ Hsu, a Northwestern astrophysicist who led the study, said: “It’s exciting to discover such an extreme system. In principle, we knew these systems should exist, but no such systems had been identified yet.”
Hsu is a postdoctoral researcher at Northwestern’s Center for Interdisciplinary Exploration and Research in Astrophysics(CIERA). He began this study while a PhD student at UC San Diego, where he was advised by Professor Adam Burgasser.
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Strange binary system
The team first discovered the strange binary system while exploring archival data.
Hsu developed an algorithm that can model a star based on its spectral data. By analysing the spectrum of light emitted from a star, astrophysicists can determine the star’s chemical composition, temperature, gravity and rotation.
This analysis also shows the star’s motion as it moves toward and away from the observer, known as radial velocity.
When examining the spectral data of LP 413-53AB, Hsu noticed something strange.
Early observations caught the system when the stars were roughly aligned and their spectral lines overlapped, leading Hsu to believe it was just one star. But as the stars moved in their orbit, the spectral lines shifted in opposite directions, splitting into pairs in later spectral data.
Hsu realised there were actually two stars locked into an incredibly tight binary.
Using powerful telescopes at the WM Keck Observatory, Hsu decided to observe the phenomenon for himself. In March 2022, the team turned the telescopes toward the constellation Taurus, where the binary system is located, and observed it for two hours. Then, they followed up with more observations in July, October and December as well as January 2023.
Burgasser said: “When we were making this measurement, we could see things changing over a couple of minutes of observation. Most binaries we follow have orbit periods of years. So, you get a measurement every few months. Then, after a while, you can piece together the puzzle.
“With this system, we could see the spectral lines moving apart in real time. It’s amazing to see something happen in the universe on a human timescale.”
Ejection of a third
The observations confirmed what Hsu’s model predicted. The distance between the two stars is about 1% of the distance between the Earth and the sun.
Burgasser said: “This is remarkable, because when they were young, something like one million years old, these stars would have been on top of each other.”
The team speculates that the stars either migrated toward each other as they evolved, or they could have come together after the ejection of a third – now lost – stellar member. More observations are needed to test these ideas.
Hsu also said that by studying similar star systems researchers can learn more about potentially habitable planets beyond Earth.
Ultracool dwarfs are much fainter and dimmer than the sun, so any worlds with liquid water on their surfaces – a crucial ingredient to form and sustain life – would need to be much closer to the star. However, for LP 413-53AB, the habitable zone distance happens to be the same as the stellar orbit, making it impossible to form habitable planets in this system.
Hsu said: “These ultracool dwarfs are neighbours of our sun. To identify potentially habitable hosts, it’s helpful to start with our nearby neighbours.
“But if close binaries are common among ultracool dwarfs, there may be few habitable worlds to be found.”
To fully explore these scenarios, Hsu, Burgasser and their collaborators hope to pinpoint more ultracool dwarf binary systems to create a full data sample. New observational data could help strengthen theoretical models for binary-star formation and evolution.
The research is published in the Astrophysical Journal Letters.
Image: Illustration of the oldest known pair of ultracool dwarf stars that orbit each other so closely, they take less than one Earth day to revolve around each other. © Adam Burgasser/ UC San Diego.