Utilizing NASA’s Imaging X-ray Polarimetry Explorer (IXPE) spacecraft, astronomers have obtained their first view of the internal area round a lifeless white dwarf star that’s vampirically feeding on a stellar companion.
The workforce from the Massachusetts Institute of Know-how (MIT) was in a position to carry out an in depth examine of the beforehand inaccessible extremely energetic area instantly surrounding a white dwarf within the system EX Hydrae, situated round 200 light-years from Earth.
Not solely did the researchers uncover a excessive diploma of polarization among the many X-rays, which describes settlement within the route the waves that comprise electromagnetic radiation are angled in, however they had been additionally in a position to hint this energetic radiation to a 2,000-mile-tall (3,200 kilometers) column of blisteringly scorching stellar materials being pulled from the companion star, dropping onto the white dwarf.
That is round half the radius of the white dwarf itself and far bigger than scientists had beforehand estimated for such a construction. The workforce additionally detected X-rays reflecting off the floor of the white dwarf earlier than being scattered, one thing that has been predicted however was by no means beforehand confirmed.
Intermediate polars earned their title attributable to variations within the energy of white dwarfs’ magnetic fields. When the magnetic discipline is especially sturdy, these lifeless stars pull materials from their companion stars, which then flows towards the white dwarfs’ poles. Nonetheless, when the magnetic fields of white dwarfs are weak, stripped materials kinds swirling buildings known as accretion disks round white dwarfs. From there, this stolen stellar matter is then step by step fed to the surfaces of the stellar remnants.
The scenario is extra complicated for vampire white dwarfs with intermediate-strength magnetic fields. Scientists have predicted that, for these techniques, an accretion disk ought to nonetheless be fashioned, nevertheless it ought to be dragged towards the poles of those white dwarfs. The magnetic fields in these techniques ought to then hoist up this materials, making a fountain of stellar matter, or an “accretion curtain,” that rains down on white dwarfs’ magnetic poles at tens of millions of miles per hour.
Scientists have predicted that this downward-flowing materials ought to slam into still-falling matter beforehand lifted by magnetic fields, creating columns of turbulent fuel that may attain temperatures of tens of millions of levels Fahrenheit, emitting X-rays within the course of.
In January 2025, the analysis workforce aimed to check this concept by finding out the EX Hydrae system with round seven Earth-days’ value of observations performed with IXPE.
The findings reveal the effectiveness of a method known as “X-ray polarimetry,” which measures the polarization of X-rays, in finding out excessive and violent stellar environments.
“We confirmed that X-ray polarimetry can be utilized to make detailed measurements of the white dwarf’s accretion geometry,” workforce chief Sean Gunderson, from MIT’s Kavli Institute for Astrophysics and Area Analysis, mentioned in a press release. “It opens the window into the potential of making related measurements of different varieties of accreting white dwarfs that even have by no means had predicted X-ray polarization alerts.”
Polarized findings
Waves of sunshine oscillate at a proper angle to the route by which that gentle is propagating, however the angle at which they oscillate might be influenced by magnetic and electrical fields. Moreover, when gentle bounces off a floor, it may change into polarized, that means the oscillation of sunshine waves is organized into a typical route. By finding out polarized gentle, researchers can study extra in regards to the object it has scattered off.
Launched in 2021, IXPE is NASA’s first mission designed to detect polarized X-rays, with the spacecraft having studied a few of the universe’s most excessive objects and occasions, resembling neutron stars, black holes, and supernovae. That is the primary time that IXPE has been directed to check an intermediate polar system, a smaller object however nonetheless a robust emitter of X-rays.
“We began speaking about how a lot polarization can be helpful to get an thought of what is taking place in most of these techniques, which most telescopes see as only a dot of their discipline of view,” mentioned workforce member Herman Marshall of MIT. “With each X-ray that is available in from the supply, you possibly can measure the polarization route. You gather a number of these, and so they’re all at totally different angles and instructions, which you’ll common to get a most well-liked diploma and route of the polarization.”
Marshall, Gunderson and colleagues discovered an 8% polarization diploma in X-rays from EX Hydrae, which is far greater than theoretical fashions predicted. Following this discovery, the scientists confirmed that the X-rays did certainly originate from a column of colliding fuel that’s round 2,000 miles tall.
“If you happen to had been in a position to stand considerably near the white dwarf’s pole, you’ll see a column of fuel stretching 2,000 miles into the sky, after which fanning outward,” Gunderson mentioned.
By measuring the route of the polarization of those X-rays, the workforce was in a position to verify that this high-energy radiation is bouncing off the floor of the white dwarf earlier than touring by way of area.
“The factor that is useful about X-ray polarization is that it is providing you with an image of the innermost, most energetic portion of this complete system,” workforce member and MIT scientist Swati Ravi added. “Once we look by way of different telescopes, we do not see any of this element.”
The workforce now intends to increase its investigation of the environments round vampire stars past EX Hydrae to different feeding white dwarf techniques. This might in the end assist higher perceive the ultimate state of those techniques — the Sort Ia supernova explosions that emerge from the overfeeding of the lifeless stars and normally outcome within the complete destruction of the white dwarf.
“There comes some extent the place a lot materials is falling onto the white dwarf from a companion star that the white dwarf cannot maintain it anymore, the entire thing collapses and produces a kind of supernova that is observable all through the universe, which can be utilized to determine the scale of the universe,” Marshall concluded. “So, understanding these white dwarf techniques helps scientists perceive the sources of these supernovae, and tells you in regards to the ecology of the galaxy.”
The workforce’s analysis was printed on Nov. 10 in The Astrophysical Journal.
