An unprecedented new telescope image of the Milky Way galaxy’s turbulent
center has revealed nearly 1,000 mysterious strands, inexplicably dangling
in space.
Stretching up to 150 light years long, the one-dimensional strands (or
filaments) are found in pairs and clusters, often stacked equally spaced,
side by side like strings on a harp. Using observations at radio
wavelengths, Northwestern University’s Farhad Yusef-Zadeh discovered the
highly organized, magnetic filaments in the early 1980s. The mystifying
filaments, he found, comprise cosmic ray electrons gyrating the magnetic
field at close to the speed of light. But their origin has remained an
unsolved mystery ever since.
Now, the new image has exposed 10 times more filaments than previously
discovered, enabling Yusef-Zadeh and his team to conduct statistical studies
across a broad population of filaments for the first time. This information
potentially could help them finally unravel the long-standing mystery.
The study was published online today by The Astrophysical Journal Letters.
“We have studied individual filaments for a long time with a myopic view,”
said Yusef-Zadeh, the paper’s lead author. “Now, we finally see the big
picture — a panoramic view filled with an abundance of filaments. Just
examining a few filaments makes it difficult to draw any real conclusion
about what they are and where they came from. This is a watershed in
furthering our understanding of these structures.”
Yusef-Zadeh is a professor of physics and astronomy at Northwestern’s
Weinberg College of Arts and Sciences and a member of the Center for
Interdisciplinary Exploration and Research in Astrophysics (CIERA).
Constructing the image
To construct the image with unprecedented clarity and detail, astronomers
spent three years surveying the sky and analyzing data at the South African
Radio Astronomy Observatory (SARAO). Using 200 hours of time on SARAO’s
MeerKAT telescope, researchers pieced together a mosaic of 20 separate
observations of different sections of the sky toward the center of the Milky
Way galaxy, 25,000 light years from Earth.
The full image will be published in an additional, accompanying paper— led
by Oxford University astrophysicist Ian Heywood and co-authored by
Yusef-Zadeh — in a forthcoming issue of The Astrophysical Journal. Along
with the filaments, the image captures radio emissions from numerous
phenomena, including outbursting stars, stellar nurseries and new supernova
remnants.
“I’ve spent a lot of time looking at this image in the process of working on
it, and I never get tired of it,” Heywood said. “When I show this image to
people who might be new to radio astronomy, or otherwise unfamiliar with it,
I always try to emphasize that radio imaging hasn’t always been this way,
and what a leap forward MeerKAT really is in terms of its capabilities. It’s
been a true privilege to work over the years with colleagues from SARAO who
built this fantastic telescope.”
To view the filaments at a finer scale, Yusef-Zadeh’s team used a technique
to remove the background from the main image in order to isolate the
filaments from the surrounding structures. The resulting picture astounded
him.
“It’s like modern art,” he said. “These images are so beautiful and rich,
and the mystery of it all makes it even more interesting.”
What we know
While many mysteries surrounding the filaments remain, Yusef-Zadeh has been
able to piece together more of the puzzle. In their latest paper, he and his
collaborators specifically explored the filaments’ magnetic fields and the
role of cosmic rays in illuminating the magnetic fields.
The variation in radiation emitting from the filaments is very different
from that of the newly uncovered supernova remnant, suggesting that the
phenomena have different origins. It is more likely, the researchers found,
that the filaments are related to past activity of the Milky Way’s central
supermassive black hole rather than coordinated bursts of supernovae. The
filaments also could be related to enormous, radio-emitting bubbles, which
Yusef-Zadeh and collaborators discovered in 2019.
And, while Yusef-Zadeh already knew the filaments are magnetized, now he can
say magnetic fields are amplified along the filaments, a primary
characteristic all the filaments share.
“This is the first time we have been able to study statistical
characteristics of the filaments,” he said. “By studying the statistics, we
can learn more about the properties of these unusual sources.
“If you were from another planet, for example, and you encountered one very
tall person on Earth, you might assume all people are tall. But if you do
statistics across a population of people, you can find the average height.
That’s exactly what we’re doing. We can find the strength of magnetic
fields, their lengths, their orientations and the spectrum of radiation.”
What we don’t know
Among the remaining mysteries, Yusef-Zadeh is particularly puzzled by how
structured the filaments appear. Filaments within clusters are separated
from one another at perfectly equal distances — about the distance from
Earth to the sun.
“They almost resemble the regular spacing in solar loops,” he said. “We
still don’t know why they come in clusters or understand how they separate,
and we don’t know how these regular spacings happen. Every time we answer
one question, multiple other questions arise.”
Yusef-Zadeh and his team also still don’t know whether the filaments move or
change over time or what is causing the electrons to accelerate at such
incredible speeds.
“How do you accelerate electrons at close to the speed of light?” he asked.
“One idea is there are some sources at the end of these filaments that are
accelerating these particles.”
What’s next
Yusef-Zadeh and his team are currently identifying and cataloging each
filament. The angle, curve, magnetic field, spectrum and intensity of each
filament will be published in a future study. Understanding these properties
will give the astrophysics community more clues into the filaments’ elusive
nature.
The MeerKAT telescope, which launched in July 2018, will continue to unveil
new secrets.
“We’re certainly one step closer to a fuller understanding,” Yusef-Zadeh
said. “But science is a series of progress on different levels. We’re hoping
to get to the bottom of it, but more observations and theoretical analyses
are needed. A full understanding of complex objects takes time.”
The study, “Statistical properties of the population of the galactic center
filaments: The spectral index and equipartition magnetic field,” was
supported by NASA and the National Science Foundation.
Reference:
F. Yusef-Zadeh, R. G. Arendt, M. Wardle, I. Heywood, W. Cotton, F. Camilo.
Statistical Properties of the Population of the Galactic Center Filaments: the
Spectral Index and Equipartition Magnetic Field. The Astrophysical Journal
Letters, 2022; 925 (2): L18
DOI: 10.3847/2041-8213/ac4802
Tags:
Space & Astrophysics