Physicists explain mysterious dark matter deficiency in galaxy pair
Self-interacting dark matter theory explains why two galaxies have less
dark matter than others
Date:
September 9, 2020
Source:
University of California - Riverside
Summary:
A new theory about the nature of dark matter helps explain why a
pair of galaxies about 65 million light-years from Earth contains
very little of the mysterious matter.
FULL STORY ==========================================================================
A new theory about the nature of dark matter helps explain why a pair of galaxies about 65 million light-years from Earth contains very little
of the mysterious matter, according to a study led by a physicist at
the University of California, Riverside.
==========================================================================
Dark matter is nonluminous and cannot be seen directly. Thought to make up
85% of matter in the universe, its nature is not well understood. Unlike
normal matter, it does not absorb, reflect, or emit light, making it
difficult to detect.
The prevailing dark matter theory, known as cold dark matter, or CDM,
assumes dark matter particles are collisionless, aside from gravity. A
newer second theory, called self-interacting dark matter, or SIDM,
proposes dark matter particles self-interact through a new dark
force. Both theories explain how the overall structure of the universe
emerges, but they predict different dark matter distributions in the
inner regions of a galaxy. SIDM suggests dark matter particles strongly
collide with one another in a galaxy's inner halo, close to its center.
Typically, a visible galaxy is hosted by an invisible dark matter halo --
a concentrated clump of material, shaped like a ball, that surrounds
the galaxy and is held together by gravitational forces. Recent
observations of two ultra- diffuse galaxies, NGC 1052-DF2 and NGC
1052-DF4, show, however, that this pair of galaxies contains very little,
if any, dark matter, challenging physicists' understanding of galaxy
formation. Astrophysical observations suggest NGC 1052- DF2 and NGC
1052-DF4 are likely satellite galaxies of NGC1052.
"It is commonly thought that dark matter dominates the overall mass in a galaxy," said Hai-Bo Yu, an associate professor of physics and astronomy
at UCR, who led the study. "Observations of NGC 1052-DF2 and -DF4 show, however, that the ratio of their dark matter to their stellar masses
is about 1, which is 300 times lower than expected. To resolve the
discrepancy, we considered that the DF2 and DF4 halos may be losing
the majority of their mass through tidal interactions with the massive
NGC 1052 galaxy." Using sophisticated simulations, the UCR-led team
reproduced the properties of NGC 1052-DF2 and NGC 1052-DF4 through tidal stripping -- the stripping away of material by galactic tidal forces --
by NGC1052. Because the satellite galaxies cannot hold the stripped mass
with their own gravitational forces, it effectively gets added to NGC
1052's mass.
The researchers considered both CDM and SIDM scenarios. Their
results, published in Physical Review Letters, indicate SIDM forms dark-matter-deficient galaxies like NGC 1052-DF2 and -DF4 far more
favorably than CDM, as the tidal mass loss of the inner halo is more significant and the stellar distribution is more diffuse in SIDM.
The research paper has been selected as an "editors' suggestion" by the journal, an honor that only a select few papers receive each week to
promote reading across fields.
Yu explained tidal mass loss could occur in both CDM and SIDM halos. In
CDM, the inner halo structure is "stiff" and resilient to tidal stripping, which makes it difficult for a typical CDM halo to lose sufficient inner
mass in the tidal field to accommodate observations of NGC 1052-DF2 and
-DF4. In contrast, in SIDM, dark matter self-interactions could push dark matter particles from the inner to the outer regions, making the inner
halo "fluffier" and enhancing the tidal mass loss accordingly. Further,
the stellar distribution becomes more diffuse.
"A typical CDM halo remains too massive in the inner regions even after
tidal evolution," Yu said.
Next, the team will perform a more comprehensive study of the NGC 1052
system and explore newly discovered galaxies with novel properties in
an effort to better understand the nature of dark matter.
Yu was joined in the study by Daneng Yang and Haipeng An of Tsinghua
University in Beijing, China. Yu was supported by grants from the
U.S. Department of Energy and the U.S. National Science Foundation.
========================================================================== Story Source: Materials provided by
University_of_California_-_Riverside. Original written by Iqbal
Pittalwala. Note: Content may be edited for style and length.
========================================================================== Journal Reference:
1. Daneng Yang, Hai-Bo Yu, and Haipeng An. Self-Interacting Dark
Matter and
the Origin of Ultradiffuse Galaxies NGC1052-DF2 and -DF4. Phys. Rev.
Lett., 2020 DOI: 10.1103/PhysRevLett.125.111105 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2020/09/200909132101.htm
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