A new map of dark matter in the local universe reveals several previously
undiscovered filamentary structures connecting galaxies. The map, developed
using machine learning by an international team including a Penn State
astrophysicist, could enable studies about the nature of dark matter as well
as about the history and future of our local universe.
Dark matter is an elusive substance that makes up 80% of the universe. It
also provides the skeleton for what cosmologists call the cosmic web, the
large-scale structure of the universe that, due to its gravitational
influence, dictates the motion of galaxies and other cosmic material.
However, the distribution of local dark matter is currently unknown because
it cannot be measured directly. Researchers must instead infer its
distribution based on its gravitational influence on other objects in the
universe, like galaxies.
"Ironically, it's easier to study the distribution of dark matter much
further away because it reflects the very distant past, which is much less
complex," said Donghui Jeong, associate professor of astronomy and
astrophysics at Penn State and a corresponding author of the study. "Over
time, as the large-scale structure of the universe has grown, the complexity
of the universe has increased, so it is inherently harder to make
measurements about dark matter locally."
Previous attempts to map the cosmic web started with a model of the early
universe and then simulated the evolution of the model over billions of
years. However, this method is computationally intensive and so far has not
been able to produce results detailed enough to see the local universe. In
the new study, the researchers took a completely different approach, using
machine learning to build a model that uses information about the
distribution and motion of galaxies to predict the distribution of dark
matter.
The researchers built and trained their model using a large set of galaxy
simulations, called Illustris-TNG, which includes galaxies, gasses, other
visible matter, as well as dark matter. The team specifically selected
simulated galaxies comparable to those in the Milky Way and ultimately
identified which properties of galaxies are needed to predict the dark
matter distribution.
"When given certain information, the model can essentially fill in the gaps
based on what it has looked at before," said Jeong. "The map from our models
doesn't perfectly fit the simulation data, but we can still reconstruct very
detailed structures. We found that including the motion of galaxies—their
radial peculiar velocities—in addition to their distribution drastically
enhanced the quality of the map and allowed us to see these details."
The research team then applied their model to real data from the local
universe from the Cosmicflow-3 galaxy catalog. The catalog contains
comprehensive data about the distribution and movement of more than 17
thousand galaxies in the vicinity of the Milky Way—within 200 megaparsecs.
The resulting map of the local cosmic web is published in a paper appearing
online May 26 in the Astrophysical Journal.
The map successively reproduced known prominent structures in the local
universe, including the 'local sheet'—a region of space containing the Milky
Way, nearby galaxies in the 'local group,' and galaxies in the Virgo
cluster—and the 'local void'—a relatively empty region of space next to the
local group. Additionally, it identified several new structures that require
further investigation, including smaller filamentary structures that connect
galaxies.
"Having a local map of the cosmic web opens up a new chapter of cosmological
study," said Jeong. "We can study how the distribution of dark matter
relates to other emission data, which will help us understand the nature of
dark matter. And we can study these filamentary structures directly, these
hidden bridges between galaxies."
For example, it has been suggested that the Milky Way and Andromeda galaxies
may be slowly moving toward each other, but whether they may collide in many
billions of years remains unclear. Studying the dark matter filaments
connecting the two galaxies could provide important insights into their
future.
"Because dark matter dominates the dynamics of the universe, it basically
determines our fate," said Jeong. "So we can ask a computer to evolve the
map for billions of years to see what will happen in the local universe. And
we can evolve the model back in time to understand the history of our cosmic
neighborhood."
The researchers believe they can improve the accuracy of their map by adding
more galaxies. Planned astronomical surveys, for example using the James Web
Space Telescope, could allow them to add faint or small galaxies that have
yet to be observed and galaxies that are further away.
Reference:
Astrophysical Journal (2021). DOI:
10.3847/1538-4357/abf040
Tags:
Space & Astrophysics