Does dark matter follow the same
laws as ordinary matter? The mystery of this invisible and hypothetical
component of our universe—which neither emits nor reflects light—remains
unsolved. A team involving members from the University of Geneva (UNIGE) set
out to determine whether, on a cosmological scale, this matter behaves like
ordinary matter or whether other forces come into play.
Their findings, published in Nature Communications, suggest a
similar behavior, while leaving open the possibility of an as-yet-unknown
interaction. This breakthrough sheds a little more light on the properties of
this elusive matter, which is five times more abundant than ordinary matter.
Ordinary
matter obeys four well-identified forces: gravity, electromagnetism, and the
strong and weak forces at the atomic level. But what about dark matter?
Invisible and elusive, it could be subject to the same laws or governed by a
fifth, as yet unknown force.
To unravel
this mystery, a team led by UNIGE set out to determine whether, on a cosmic
scale, dark matter falls into gravitational wells in the same way as ordinary
matter. Under the influence of massive celestial bodies, the space occupied by
our universe is distorted, creating wells. Ordinary matter—planets, stars
and galaxies—falls into these
wells according to well-established physical laws, including Einstein's theory
of general relativity and
Euler's equations. But what about dark matter?
"To
answer this question, we compared the velocities of galaxies across the
universe with the depth of gravitational wells," explains Camille Bonvin,
associate professor in the Department of Theoretical Physics at UNIGE's Faculty
of Science and co-author of the study.
"If dark
matter is not subject to a fifth force, then galaxies—which are mostly made of
dark matter—will fall into these wells like ordinary matter, governed solely by
gravity. On the other hand, if a fifth force acts on dark matter, it will
influence the motion of galaxies, which would then fall into the wells
differently. By comparing the depth of the wells with the galaxies' velocities,
we can therefore test for the presence of such a force."
Euler's equations still valid
Applying this
approach to current cosmological data, the research team concluded that dark
matter falls into gravitational wells in the same way as ordinary matter, thus
obeying Euler's equations.
"At this
stage, however, these conclusions do not yet rule out the presence of an
unknown force. But if such a fifth force exists, it cannot exceed 7% of the
strength of gravity—otherwise it would already have appeared in our
analyses," says Nastassia Grimm, first author of the study and former
postdoctoral researcher at the Department of Theoretical Physics at UNIGE's
Faculty of Science who has recently joined the Institute of Cosmology and
Gravitation at the University of Portsmouth.
These initial
results mark a major step forward in characterizing dark matter. The next
challenge will be to determine whether a fifth force governs it.
"Upcoming data from the newest experiments, such as LSST and DESI, will be sensitive to forces as weak as 2% of gravity. They should therefore allow us to learn even more about the behavior of dark matter," concludes Isaac Tutusaus, researcher at ICE-CSIC and IEEC and associate professor at IRAP, Midi-Pyrénées observatory, University of Toulouse, co-author of the study.
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