NASA’s IXPE (Imaging X-ray Polarimetry Explorer) has helped astronomers better understand the shapes of structures essential to a black hole – specifically, the disk of material swirling around it, and the shifting plasma region called the corona.
The stellar-mass black hole, part of the
binary system Swift J1727.8-1613, was discovered in the summer of 2023 during
an unusual brightening event that briefly caused it to outshine nearly all
other X-ray sources. It is the first of its kind to be observed by IXPE as it
goes through the start, peak,
and conclusion of an X-ray outburst like this.
This illustration shows NASA’s Imaging X-ray
Polarimetry Explorer (IXPE) spacecraft, at lower left, observing the newly
discovered binary system Swift J1727.8-1613 from a distance. At the center is a
black hole surrounded by an accretion disk, shown in yellow and orange, and a
hot, shifting corona, shown in blue. The black hole is siphoning off gas from
its companion star, seen behind the black hole as a red sphere. Jets of
fast-moving, superheated particles stream from both poles of the black hole.
Credit: Marie Novotná
Swift J1727 is the subject of a series of new studies published in The
Astrophysical Journal and Astronomy & Astrophysics.
Scientists say the findings provide new insight into the behavior and evolution
of black hole X-ray binary systems.
“This outburst evolved incredibly
quickly,” said astrophysicist Alexandra Veledina, a permanent researcher at the
University of Turku, Finland. “From our first detection of the outburst, it
took Swift J1727 just days to peak. By then, IXPE and numerous other telescopes
and instruments were already collecting data. It was exhilarating to observe
the outburst all the way through its return to inactivity.”
Until late 2023, Swift J1727
briefly remained brighter than the Crab Nebula, the standard X-ray “candle”
used to provide a baseline for units of X-ray brightness. Such outbursts are
not unusual among binary star systems, but rarely do they occur so brightly and
so close to home – just 8,800 light years from Earth. The binary system was
named in honor of the Swift
Gamma-ray Burst Mission which initially detected the outburst with its Burst Alert Telescope
on Aug. 24, 2023, resulting in the discovery of the black hole.
X-ray binary systems typically
include two close-proximity stars at different stages of their lifecycle. When
the elder star runs out of fuel, it explodes in a supernova, leaving behind
a neutron star, white dwarf, or black hole. In the case of Swift J1727, the powerful gravity of the resulting black
hole stripped material from its companion star, heating the material to more
than 1.8 million degrees Fahrenheit and producing a vast outpouring of X-rays.
This matter formed an accretion disk and can include a superheated corona. At the poles of the black hole, matter also can escape from the binary
system in the form of relativistic jets.
IXPE, which has helped NASA and
researchers study all these phenomena, specializes in X-ray polarization, the characteristic of light that helps map the shape and structure of
such ultra-powerful energy sources, illuminating their inner workings even when
they’re too distant for us to see directly.
“Because light itself can’t escape their gravity, we can’t see black holes.
We can only observe what is happening around them and draw conclusions about
the mechanisms and processes that occur there. IXPE is crucial to that work.
Alexandra Veledina
NASA Astrophysicist
“Because light itself can’t escape their
gravity, we can’t see black holes,” Veledina said. “We can only observe what is
happening around them and draw conclusions about the mechanisms and processes
that occur there. IXPE is crucial to that work.”
Two of the IXPE-based studies of Swift
J1727, led by Veledina and Adam Ingram, a researcher at Newcastle University in
Newcastle-upon-Tyne, England, focused on the first phases of the outburst.
During the brief period of months when the source became exceptionally bright,
the corona was the main source of observed X-ray radiation.
“IXPE documented polarization of X-ray
radiation traveling along the estimated direction of the black hole jet, hence
the hot plasma is extended in the accretion disk plane,” Veledina said.
“Similar findings were reported in the persistent black hole binary
Cygnus X-1, so this finding helps verify that the
geometry is the same among short-lived eruptive systems.”
The team further monitored how
polarization values changed during Swift J1727’s peak outburst. Those
conclusions matched findings simultaneously obtained during studies of other
energy bands of electromagnetic radiation.
A third and a fourth study, led by
researchers Jiří Svoboda and Jakub Podgorný, both of the Czech Academy of
Sciences in Prague, focused on X-ray polarization at the second part of the
Swift J1727’s outburst and its return to a highly energetic state several
months later. For Podgorný’s previous efforts using IXPE data and black hole
simulations, he recently was awarded the Czech Republic’s top national prize
for a Ph.D. thesis in the natural sciences.
The polarization data indicated that the
geometry of the corona did not change significantly between the beginning and
the end of the outburst, even though the system evolved in the meantime and the
X-ray brightness dropped dramatically in the later energetic state.
The results represent a significant step
forward in our understanding of the changing shapes and structures of accretion
disk, corona, and related structures at black holes in general. The study also
demonstrates IXPE’s value as a tool for determining how all these elements of
the system are connected, as well as its potential to collaborate with other
observatories to monitor sudden, dramatic changes in the
cosmos.
“Further observations of matter near black holes in binary systems are needed, but the successful first observing campaign of Swift J1727.8–1613 in different states is the best start of a new chapter we could imagine,” said Michal Dovčiak, co-author of the series of papers and leader of the IXPE working group on stellar-mass black holes, who also conducts research at the Czech Academy of Sciences.
Source: NASA’s IXPE Details Shapes of Structures at Newly Discovered Black Hole - NASA
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