Are Galaxies Without Dark Matter Actually Real?

https://portside.org/2021-12-12/are-galaxies-without-dark-matter-actually-real
Portside Date:
Author: Ethan Siegel
Date of source:
Big Think

When we look out at the Universe, what we see is most certainly not what we get. The overwhelming majority of the Universe, for a variety of reasons, is invisible to us, and not in an intuitive sense. Most of the matter we can see — the luminous matter — comes in the form of stars, but that only accounts for a few percent of the normal, atom-based matter that’s out there. Most of the mass in the Universe, as inferred from its cumulative gravitational effects, cannot even be normal matter, but rather must be some novel type of invisible matter: dark matter, which outmasses normal matter by a 5-to-1 ratio. And beyond that, a full two-thirds of the Universe’s overall energy isn’t matter at all, but rather a novel type of energy that doesn’t clump, cluster, or gravitate in the conventional way: dark energy.

And yet, while most galaxies, including our own, have tremendous amounts of dark matter, there are a few cosmic outliers. Initially, the first couple were disputed, but a recent study claims to have discovered six new ones that have, as best as we can tell, no dark matter at all. Is this, for lack of a better word, real? And if so, what does it mean? That’s what Justin Briggs wants to know, asking:

“Hey, Starts With A Bang, is this [story] as weird as it sounds, or just link bait?”

The story he’s referring to is that of not just one galaxy without dark matter, but six, based on this new peer-reviewed and recently published study. There’s a fascinating amount of science here, so let’s dive in to show you what it’s all about.

A spiral galaxy like the Milky Way rotates as shown at right, not at left, indicating the presence of dark matter. However, the gravitational influence of other stars and stellar remnants will perturb the motion of any individual star, making long-term predictions all but impossible. (Credit: Ingo Berg/Wikimedia Commons; Acknowledgement: E. Siegel)

There’s an overwhelming amount of astrophysical evidence — albeit indirect evidence — supporting the existence of dark matter in the Universe. To briefly recap:

Additionally, we see that normal matter alone cannot explain the motions of:

On top of that, we also have evidence of dark matter from gravitational lensing, including, most strikingly, from colliding galaxy clusters, which shows that there is plenty of gravitating mass where the normal matter is not.

The X-ray (pink) and overall matter (blue) maps of various colliding galaxy clusters show a clear separation between normal matter and gravitational effects, some of the strongest evidence for dark matter. Although some of the simulations we perform indicate that a few clusters may be moving faster than expected, the simulations include gravitation alone, and other effects like feedback, star formation, and stellar cataclysms may also be important for the gas. Without dark matter, these observations (along with many others) cannot be sufficiently explained. (Credit: NASA, ESA, D. Harvey (École Polytechnique Fédérale de Lausanne, Switzerland; University of Edinburgh, UK), R. Massey (Durham University, UK), T. Kitching (University College London, UK), and A. Taylor and E. Tittley (University of Edinburgh, UK))

And yet, all of these observations, a puzzle to explain on their own, immediately fall into line with a single, compelling, and self-consistent story if we add one ingredient to the Universe: a form of massive matter that clumps, gravitates, and moves slowly compared to the speed of light, in about five times the abundance of normal matter. We call this dark matter, though it’s not actually “dark;” dark things absorb light and don’t emit any, while this form of matter is actually invisible, not interacting with light or colliding with normal matter (or itself) in any discernible way.

When we examine the details of the cosmic web, and how the galaxies form and evolve within it, again, dark matter is absolutely required. But there’s a longstanding prediction that had, for many years, puzzled theorists and observers alike. You see, if dark matter exists, then every massive clump in the Universe, when it first forms, should consist of both dark matter and normal matter in approximately the same ratio as the overall, cosmic one: about a 5-to-1 ratio. As the Universe evolves, however, things get messy.

Normal matter collides inelastically, contracts, sheds momentum and angular momentum, and forms stars. Radiation from new stars push the normal matter outwards, but not the dark matter. Proto-galaxies gravitationally interact; normal matter gets stripped from fast-moving galaxies in gas-rich environments; mergers occur; etc.

The cosmic web that we see, the largest-scale structure in the entire Universe, is dominated by dark matter. On smaller scales, however, baryons can interact with one another and with photons, leading to stellar structure but also leading to events that can separate dark matter from normal matter. Surprisingly, the existence of dark matter-free structures confirms the need for dark matter in our Universe. (Credit: Ralf Kaehler/SLAC National Accelerator Laboratory)

As a result of all of this, we expect three sets of galactic populations:

  1. Large, massive galaxies, with the same overall dark matter-to-normal matter ratio as the overall cosmos and the largest structures of all: approximately 5 to 1.
  2. Small, less massive galaxies, where things like star formation have previously occurred, expelling much of the normal matter. These galaxies are expected to have greater dark matter-to-normal matter ratios than the cosmic average, where the smallest, lowest-mass examples might have ratios of hundreds-to-1 or even more extreme.
  3. A rare population of galaxies that form from the normal matter that gets stripped out of their dark matter halos entirely: dark matter-poor or even dark matter-free galaxies, where the dark matter-to-normal matter ratio is far less than 5 to 1, and may even be as low as zero in some galaxies.

For a long time, only the first two types of galaxies had been seen. Moreover, the second population of galaxies appeared to obey a relatively tight correlation: the baryonic Tully-Fisher relation, where only the normal matter component of galaxies was necessary for predicting their behavior, regardless of overall mass or the underlying, assumed dark matter ratios.

When galaxies like the spiral galaxy at right, D100, speed through a rich environment, the friction with the environment can cause gas stripping, leading to the formation of stars and increasing the dark matter-to-normal matter ratio of the host galaxy. A few of these stripped star clusters that form, trailing the galaxy, could later re-form into a dark matter-free galaxy of their own. (Credit: NASA, ESA, M. Sun (University of Alabama), and W. Cramer and J. Kenney (Yale University))

Detractors of dark matter pointed to this as evidence that the dark matter paradigm must be incorrect, but most researchers had a different take on it. Either these galaxies were out there but faint and difficult to characterize, or that most of them formed close by other large, massive galaxies, which would tear them apart on timescales that were short relative to the age of the Universe.

One of the remarkable things about these scenarios is that they’re extremely different from one another, and that lends itself to an observational test. If dark matter is incorrect as a paradigm overall, then the properties of each galaxy should be determined by the presence, abundance, and distribution of normal matter alone. On the other hand, if dark matter exists, then we should be able to search for two classes of galaxies that hasn’t been identified before. If they exist, they would support the existence of dark matter in the cosmos; if not, their absence would call the viewpoint that the Universe contains ample amounts of dark matter into question, justifying the doubts put forth by the contrarians in the community.

Many nearby galaxies, including all the galaxies of the local group (mostly clustered at the extreme left), display a relationship between their mass and velocity dispersion that indicates the presence of dark matter. NGC 1052-DF2 is the first known galaxy that appears to be made of normal matter alone, and was later joined by DF4 earlier in 2019. Galaxies like Segue 1 and Segue 3, however, are very high up and clustered towards the left of this chart; these are the most dark matter-rich galaxies known: the smallest and lowest-mass ones. (Credit: S. Danieli et al., ApJL, 2019)

One population of galaxies that ought to exist would be small, diffuse satellite galaxies found in the vicinities of larger ones. These galaxies should be relatively short-lived, so we should be able to witness them being destroyed through tidal, gravitational interactions from the outside looking inward. These galaxies would be faint and low in both overall mass and overall brightness, so we’d have to search the local neighborhood very carefully to make sure we’re finding and characterizing them properly. Moreover, we might even be able to find stellar streams emanating from these galaxies: evidence that they’re in the process of being tidally torn apart.

The second population that ought to exist would be larger, more massive, but relatively isolated galaxies that had their dark matter stripped away long ago. These galaxies should also be rare, but since there are many types of interactions that can separate normal matter from dark matter, it’s reasonable to expect that some of that normal matter will remain clumped together and gravitationally bound. Over time, if it were sufficiently isolated from other massive objects, it could persist, leading to a new population of field galaxies that were faint, diffuse, and nearly completely devoid of dark matter.

The first galaxy detected that supports its existence without dark matter, NGC 1052-DF2, is shown here as imaged by Hubble. The follow-up imaging was done in order to determine whether it was gravitationally connected to NGC 1052, at ~64 million light-years away, or NGC 1042, much closer at 42 million light-years distant. The determination was 72 million light-years with an uncertainty of just a few percent, and hence, it cannot have a normal amount of dark matter. (Credit: Z. Shen et al., ApJ, 2021)

Only a few years ago, the first two examples of candidate galaxies that fell into the first category were discovered. (Or more accurately, since they were previously known, they were characterized.) There’s a region of the sky that possesses three relatively large, massive galaxies: NGC 1052, NGC 1042, and NGC 1035, all well-separated from one another. While searching for galaxies using the Dragonfly Telephoto Array, a team led by Shany Danieli and Pieter van Dokkum of Yale discovered and characterized a number of small satellite galaxies that appeared to be bound to NGC 1052, a large elliptical galaxy. Importantly, two of them were ultra-diffuse dwarf galaxies, and they appeared to lack the dark matter expected to be found within them. Dubbed NGC 1052-DF2, discovered in 2018, and NGC 1052-DF4, found the next year in 2019, they immediately set off a firestorm of research.

Could these galaxies be explained with MOdified Newtonian Dynamics instead of as a galaxy lacking dark matter? Were we measuring the distance to the dwarf galaxies incorrectly? Were they actually associated with one of the other galaxies located nearly along the same line of sight: NGC 1042 or NGC 1035? Could the host galaxy, NGC 1052, actually be deficient in dark matter?

As follow-up observations with a superior instrument — the Hubble Space Telescope — showed, the answer to all of these questions is “no.” The velocity dispersion is too low and the distance to these galaxies is too great; they really do have slow-moving stars and extremely small, and possibly no, dark matter inside.

The galaxy NGC 1052-DF4, one of the two satellite galaxies of NGC 1052 determined to be devoid of dark matter internally, shows evidence of being tidally disrupted; an effect more easily seen in the panel at right, once the surrounding light sources are accurately modeled and removed. Galaxies such as this are unlikely to live long in rich environments without dark matter to hold them together. (Credit: M. Montes et al., ApJ, 2020)

Additionally, one of these galaxies, NGC 1052-DF4, is presently undergoing tidal disruption: evidence that the gravitational forces from the larger, more massive, surrounding galaxies are in the process of tearing it apart. It’s being sheared and shredded apart from the outside in, which means that the most tenuously held outer parts are getting ejected first. As the galaxy loses its mass, it evolved to become more diffuse, and then even the stellar components start to get ejected in tidal streams. The fact that a small tidal stream has now been observed could be a hint: perhaps these galaxies are only dark matter-free right now; perhaps earlier, they had “normal” amounts of dark matter, and perhaps in the future, they’ll be torn apart entirely.

But what about that second population of expected galaxies: the larger, more massive ones without dark matter that could persist if they’re sufficiently isolated from other large, massive galaxies?

That is — to go way back to the original question — where the new study being touted in the popular media comes into play. Led by Pavel E. Mancera Piña and published in the Astrophysical Journal Letters back in 2019 (honestly, I have no idea why it’s suddenly popular now?), they identify six independent galaxies, all sufficiently isolated from others, with large reservoirs of neutral hydrogen gas. They’re all diffuse, massive, and, most importantly, their stars move with very, very slow internal motions, consistent with having no dark matter inside at all.

Across a wide range of masses, galaxies all fell along a relationship called the baryonic Tully-Fisher relation, where the observed/inferred rotational speed was determined by the normal matter alone, irrespective of dark matter. The existence of a population of galaxies that do not follow this rule provides strong evidence for a fundamentally different population: a set of galaxies without dark matter, following the grey line. (Credit: P.E. Mancera Piña et al., ApJL, 2019)

This is, if it holds up, absolutely groundbreaking. Each of the six galaxies, on the whole, are all:

The methods used by the authors of the paper are completely standard in the field. None of them are either edge-on or face-on, eliminating a potential systematic error, and three additional galaxies that also show the same effect were excluded from this study because the data on them were not as pristine.

In other words, these are gold-standard detections, and they fly in the face of a number of dark matter alternatives. Perhaps most importantly, when you take these six dark matter-free galaxies and you look at them alongside NGC 1052-DF2 and NGC 1052-DF4 (commonly shortened to DF2 and DF4 in the literature), you can see that both populations of galaxies are consistent with containing no dark matter, and with one another.

When compared with galaxies that appear to be rich in dark matter, following the dotted line at the bottom, we can see that galaxies such as DF2 and DF4, at left, as well as more massive galaxies found in isolation, with orange stars, both appear to have little, and possibly even no, dark matter at all. These galaxies without dark matter, or dark matter-free galaxies, cannot coexist with dark matter-rich ones unless dark matter exists. (Credit: P.E. Mancera Piña et al., ApJL, 2019)

Scientists, you must understand, are a notoriously skeptical bunch. Convincing the overwhelming majority of any subfield of science that things are one particular way only occurs when the supporting evidence is also overwhelming. Although the astrophysical evidence in favor of dark matter reached that point long ago, we must always remember that continually testing our assumptions and gathering more and improved data about the Universe is the only way by which science can continue to advance. As soon as we’ve decided that we already know all there is to know, we’re right. The moment we stop asking questions and investigating the apparent gaps in our understanding is the moment we’ve lost the opportunity to uncover anything new.

Those who attempt to explain the Universe without dark matter now have an additional obstacle to contend with: a prediction of dark matter that had long gone unverified, that galaxies explicable by their normal matter alone should exist, has finally come to fruition. Not only that, but both types of such galaxies predicted to exist — satellite galaxies that won’t live for long, and major galaxies that can persist for billions of years in isolation — have now been found, with multiple examples of each. It’s a beautiful success story for dark matter, and one more piece of the cosmic puzzle that appears to have fallen neatly into place.

Send in your Ask Ethan questions to startswithabang@gmail.com!


Ethan Siegel is a Ph.D. astrophysicist and author of "Starts with a Bang!" He is a science communicator, who professes physics and astronomy at various colleges. He has won numerous awards for science writing since 2008 for his blog, including the award for best science blog by the Institute of Physics. His two books "Treknology: The Science of Star Trek from Tricorders to Warp Drive" and "Beyond the Galaxy: How humanity looked beyond our Milky Way and discovered the entire Universe" are available for purchase at Amazon. Follow him on Twitter @startswithabang.

Get Big Think in Your Inbox. Subscribe for counterintuitive, surprising, and impactful stories delivered to your inbox every Thursday.


Source URL: https://portside.org/2021-12-12/are-galaxies-without-dark-matter-actually-real