Even though the sensitivity of dark matter detectors has improved by more than five orders of magnitude since the early 1980s, all results so far are compatible with zero events. The searches for axions, another popular dark matter candidate, haven’t fared any better. Coming generations of dark matter experiments will cross into the regime where the neutrino background becomes comparable to the expected signal. But, as a colleague recently pointed out to me, this merely means that the experimentalists have to understand the background better.
Maybe in 100 years they’ll still sit in caves, deep underground. And wait.
Meanwhile others are running out of patience. Particle dark matter is a great explanation for all the cosmological observations that general relativity sourced by normal matter cannot explain. But maybe it isn’t right after all. The alternative to using general relativity and adding particle is to modify general relativity so that space-time curves differently in response to the matter we already know.
Already in the mid 1980s, Modehai Milgrom showed that modifying gravity has the potential to explain observations commonly attributed to particle dark matter. He proposed Modified Newtonian Dynamics – short MOND – to explain the galactic rotation curves instead of adding particle dark matter. Intriguingly, MOND, despite it having only one free parameter, fits a large number of galaxies. It doesn’t work well for galaxy clusters, but this clearly shows that many galaxies are similar in very distinct ways, ways that the concordance model (also known as LambdaCDM) hasn’t been able to account for.
In its simplest form the concordance model has sources which are collectively described as homogeneous throughout the universe – an approximation known as the cosmological principle. In this form, the concordance model doesn’t predict how galaxies rotate – it merely describes the dynamics on supergalactic scales.
To get galaxies right, physicists have to also take into account astrophysical processes within the galaxies: how stars form, which stars form, where do they form, how do they interact with the gas, how long do they live, when and how they go supernova, what magnetic fields permeate the galaxies, how the fields affect the intergalactic medium, and so on. It’s a mess, and it requires intricate numerical simulations to figure out just exactly how galaxies come to look how they look.
And so, physicists today are divided in two camps. In the larger camp are those who think that the observed galactic regularities will eventually be accounted for by the concordance model. It’s just that it’s a complicated question that needs to be answered with numerical simulations, and the current simulations aren’t good enough. In the smaller camp are those who think there’s no way these regularities will be accounted for by the concordance model, and modified gravity is the way to go.
In a recent paper, McGaugh et al reported a correlation among the rotation curves of 153 observed galaxies. They plotted the gravitational pull from the visible matter in the galaxies (gbar) against the gravitational pull inferred from the observations (gobs), and find that the two are closely related.
Figure from arXiv:1609.05917 [astro-ph.GA] |
This correlation – the mass-discrepancy-acceleration relation (MDAR) – so they emphasize, is not itself new, it’s just a new way to present previously known correlations. As they write in the paper:
“[This Figure] combines and generalizes four well-established properties of rotating galaxies: flat rotation curves in the outer parts of spiral galaxies; the “conspiracy” that spiral rotation curves show no indication of the transition from the baryon-dominated inner regions to the outer parts that are dark matter-dominated in the standard model; the Tully-Fisher relation between the outer velocity and the inner stellar mass, later generalized to the stellar plus atomic hydrogen mass; and the relation between the central surface brightness of galaxies and their inner rotation curve gradient.”But this was only act 1.
In act 2, another group of researchers responds to the McGaugh et al paper. They present results of a numerical simulation for galaxy formation and claim that particle dark matter can account for the MDAR. The end of MOND, so they think, is near.
Figure from arXiv:1610.06183 [astro-ph.GA] |
McGaugh, hero of act 1, points out that the sample size for this simulation is tiny and also pre-selected to reproduce galaxies like we observe. Hence, he thinks the results are inconclusive.
In act 3, Mordehai Milgrom, the original inventor of MOND – posts a comment on the arXiv. He also complains about the sample size of the numerical simulation and further explains that there is much more to MOND than the MDAR correlation. Numerical simulations with particle dark matter have been developed to fit observations, he writes, so it’s not surprising they now fit observations.
“The simulation in question attempt to treat very complicated, haphazard, and unknowable events and processes taking place during the formation and evolution histories of these galaxies. The crucial baryonic processes, in particular, are impossible to tackle by actual, true-to-nature, simulation. So they are represented in the simulations by various effective prescriptions, which have many controls and parameters, and which leave much freedom to adjust the outcome of these simulations [...]In act 4, another paper with results of a numerical simulation for galaxy structures with particle dark matter appears.
The exact strategies involved are practically impossible to pinpoint by an outsider, and they probably differ among simulations. But, one will not be amiss to suppose that over the years, the many available handles have been turned so as to get galaxies as close as possible to observed ones.”
This one uses a code with acronym EAGLE, for Evolution and Assembly of GaLaxies and their Environments. This code has “quite a few” parameters, as Aaron Ludlow, the paper’s first author told me, and these parameters have been optimized to reproduce realistic galaxies. In this simulation, however, the authors didn’t use this optimized parameter configuration but let several parameters (3-4) vary to produce a larger set of galaxies. These galaxies in general do not look like those we observe. Nevertheless, the researchers find that all their galaxies display the MDAR correlation, regardless.
This would indicate that the particle dark matter is enough to describe the observations.
Figure from arXiv:1610.07663 [astro-ph.GA] |
However, even when varying some parameters, the EAGLE code still contains parameters that have been fixed previously to reproduce observations. Ludlow calls them “subgrid parameters,” meaning they quantify physics on scales smaller than what the simulation can presently resolve. One sees for example in Figure 1 of their paper (shown below) that all those galaxies have a pronounced correlation between the velocities of the outer stars (Vmax) and the luminosity (M*) already.
Figure from arXiv:1610.07663 [astro-ph.GA] Note that the plotted quantities are correlated in all data sets, though the off-sets differ somewhat. |
One shouldn’t hold this against the model. Such numerical simulations are done for the purpose of generating and understanding realistic galaxies. Runs are time-consuming and costly. From the point of view of an astrophysicist, the question just how unrealistic galaxies can get in these simulations is entirely nonsensical. And yet that’s exactly what the modified-gravity/dark matter showoff now asks for.
In act 5, John Moffat shows that modified gravity – the general relativistic completion of MOND – reproduces the MDAR correlation, but also predicts a distinct deviation for the very outside stars of galaxies.
Figure from arXiv:1610.06909 [astro-ph.GA] The green curve is the prediction from modified gravity. |
The crucial question here is, I think, which correlations are independent of each other. I don’t know. But I’m sure there will be further acts in this drama.
"The alternative to using general relativity and adding particle is to modify general relativity so that space-time curves differently in response to the matter we already know."
ReplyDeleteJust to be clear, depending on the definition, it is not the alternative but rather one alternative. Another alternative (though probably not relevant in the MOND debate in its simple form) is macroscopic dark matter, which you have posted about before.
" John Moffat shows that modified gravity – the general relativistic completion of MOND"
The term "modified gravity" refers to a whole range of theories, not all of which are designed with MOND in mind and which might not reproduce MOND phenomenology. Most are also not by Moffat. I guess you meant "John Moffat's version of modified gravity, which is also a relativistic completion of MOND".
How would this study fit in?
ReplyDeleteHow Zwicky already ruled out modified gravity theories without dark matter
https://arxiv.org/pdf/1610.01543.pdf
"As a start, the no-dark-matter case is confirmed to work badly:
the need for dark matter starts near the cluster centre, where Newton’s law is still supposed to
be valid. This leads to the conundrum discovered by Zwicky, which is likely only solvable if the
theories assume additional (dark) matter. Neutrinos with eV masses serve well without altering the
successes in (dwarf) galaxies."
Phillip,
ReplyDeleteWith a slight abuse of terminology, I count macro dark matter as particle dark matter. It's stuff, basically, as opposed to a modification of general relativity.
Regarding the terminology. Well, Moffat calls this model modified gravity, I was thinking the polite thing would be to use this name. You're right though, it's unfortunate, as there's more than one way to modify gravity. Be that as it may, I am not aware of any other modified gravity model that comes even remotely close to Moffat's in fitting observations at this point. Best,
B.
Rob,
ReplyDeleteIt's well known that MOND doesn't work well on supergalactic scales (as I wrote). That doesn't make the regularities in galaxies go away.
"With a slight abuse of terminology, I count macro dark matter as particle dark matter. It's stuff, basically, as opposed to a modification of general relativity."
ReplyDeleteYes, it is stuff, but since you talked about lack of detection, it is relevant that conventional direct-detection experiments probably wouldn't be expected to detect macroscopic dark matter.
"Well, Moffat calls this model modified gravity, I was thinking the polite thing would be to use this name."
A bad choice on his part. Well, maybe "MOG" is "Moffat Gravity", not "modified gravity". :-)
"You're right though, it's unfortunate, as there's more than one way to modify gravity."
I've met many people who work on modified gravity (their own self-description of their work), but few or none on Moffat's MOG.
"Be that as it may, I am not aware of any other modified gravity model that comes even remotely close to Moffat's in fitting observations at this point."
Yes, definitely worth looking into. A generic term for something specific can be confusing, though.
"It's well known that MOND doesn't work well on supergalactic scales (as I wrote). That doesn't make the regularities in galaxies go away."
ReplyDeleteIndeed. Also, even MOND people concede that there is need for dark matter in clusters.
The interesting thing is that there are also missing baryons, on a range of scale. Could the dark matter in clusters be entirely baryonic? It seems that this is not completely ruled out.
Ha, Moffat Gravity, I like that! I'll totally use this in the future.
ReplyDeleteMofat Gratity to the top five. Great.
ReplyDeleteMaybe now Witten has entered on this drama: https://arxiv.org/abs/1610.08297
ReplyDeleteHave the MOND people any idea how they explain the Bullet Cluster and the CMB data? You can hold up any theory you want (greetings to Mr. Quine), but if it doesn't explain all evidence it is just not very attractive.
ReplyDelete"I'll totally use this in the future."
ReplyDeleteThat's, like, so tubular! Didn't know that you were a valley girl! I expect future posts to be in valley speak. That would be, like, so cool! Like totally!
Since Tegmark has already published a paper with the abstract in couplets, the next step is obviously incorporating valley speak into papers. "Gag me with a spoon! Those simulations are, like, just so grody!"
https://www.youtube.com/watch?v=tin2vDHG79o
Nicholas,
ReplyDeleteNot MOND. MOND is only an approximation - nobody expects it to work in general. Modified gravity has no problems with the Bullet Cluster.
"Maybe now Witten has entered on this drama: https://arxiv.org/abs/1610.08297"
ReplyDeleteWitten, though relatively famous, is only the fourth author on the paper. The second and third are much more famous among astrophysicists.
"Have the MOND people any idea how they explain the Bullet Cluster and the CMB data? You can hold up any theory you want (greetings to Mr. Quine), but if it doesn't explain all evidence it is just not very attractive."
ReplyDeleteBullet cluster? Unclear. CMB? Very unclear. However, you could just as well use your second sentence to rule out the standard model, since there is a lot of data which it doesn't explain (hence MOND).
The difference is that MOND folks admit that the CMB is good support for the standard model.
Which is more handwaving? MOND is not a relativistic theory; maybe we can understand the CMB in a relativistic extension? All galaxy phenomenology which MOND explains with one adjustable parameter will be shown to follow unambiguously from conventional physics once computers are powerful enough to do simulations which are detailed enough?
Physics postulates the Equivalence Principle [EP], then GR with achiral spacetime curvature. Baryogenesis, Tully-Fischer; parity violations, symmetry breakings, chiral anomalies, Chern-Simons repair of Einstein-Hilbert action...are unending.
ReplyDeleteEinstein-Cartan-Kibble-Sciama gravitation given achiral spacetime curvature is GR. Chiral spacetime torsion is indistinguishable given achiral challenges (socks on a left foot). Chiral challenges are opposite shoes on a left foot, non-identical minimum action trajectories, EP violation. The first paragraph is sourced.
The EP is 5×10^(-14) inert to composition and field, to all classical, quantum mechanical, relativistic, and gravitational (strong EP) divergences. Geometric opposite shoes EP violate around 10^(-10) relative, baryogenesis and Milgrom acceleration. Geometric Eötvös experiments are trivial chemistry, impossible physics.
http://thewinnower.s3.amazonaws.com/papers/95/v1/sources/image004.png
LOOK. At worst, it succeeds.
"Be that as it may, I am not aware of any other modified gravity model that comes even remotely close to Moffat's in fitting observations at this point."
ReplyDeleteWhat about Mannheims Confirmal Gravity?
IMHO most LCDM folks are stringers and SUSY advocates. CDM is their last refuge in salvaging SUSY. These folks have formidable influence in the community evidenced by winning awards without proof that their model works. Worse, they will never admit they are wrong. Yes Bee, they are prepared to dig in for at least a millenia
ReplyDelete"What about Mannheims Confirmal Gravity?"
ReplyDeleteYes? What about it?
Yes? What about it?
ReplyDeleteFittings of Confirmal Gravity to observations seems to not be really bad, too.
Reference please...
ReplyDeleteThank you, Dr. Hossenfelder, for your enlightening view into the progress of MOND and related theories. I forget who said it (von Neumann?) that given few observations and many parameters a person could "fit an elephant" into whatever theory suited his/her purposes. This seems to be the case with current non-Einsteinian gravity theories and the parameters that multiply like rabbits when various scalar, vector, tensor and spinor fields are introduced into the basic formalism.
ReplyDeleteI'm surely wrong, but I can't help seeing dark matter and dark energy as a kind of Michaelson-Morley aether that doesn't exist. The cosmological constant, coupled with some kind of consistent modified gravity theory, seems much simpler, especially in view of the lack of experimental evidence to date. Again, much thanks.
https://arxiv.org/abs/1610.08907
ReplyDeletepage 67
As they re-materialize on the transporter deck shaking their heads at the readings in their hand-held dark matter detectors, Helbig looks over at Hossenfelder, shaking his head ... "It's stuff, Bee, but not as we know it."
ReplyDeleteSabine, S is referring to https://arxiv.org/abs/1011.3495 and other papers by Mannheim. I think the problem (as I understand)
ReplyDeleteis that this theory does not agree with solar system observations.
Shantanu,
ReplyDeleteYes, I looked at this many years ago and didn't find it convincing. It won't harm though to see if anything changed since.
I have hard time understanding how mond predictions are any simpler than LCDM. Baryons still exist and keep exploding in hard to simulate ways.
ReplyDeleteThere is some hope that the LISA Pathfinder (LPF) will be able to falsify at least some of the modified gravity theories deriving from MOND in a passage or passage through a gravitational saddle point (where the net Newtonian acceleration of gravity becomes small compared to the MOND acceleration parameter) during its extended mission. (Of course, if LISA Pathfinder actually sees a signal, that would strongly motivate a follow on mission to explore this.)
ReplyDeleteSee https://arxiv.org/abs/1404.0313 for some more details.
The extended mission test should actually start soon, assuming the LPF Lagrange point mission is not itself extended, but it would take some months using WSB techniques to get LPF into the proper orbit for the saddle point fly-throughs.
The LPF web site has not been updated in some time, but my understanding is that this is going forward.
https://www.elisascience.org/articles/lisa-pathfinder/lpf-science/testing-newtonian-gravity-earth-sun-saddle-point
"Witten, though relatively famous, is only the fourth author on the paper. The second and third are much more famous among astrophysicists." Wow, that is an objective attitude: fame as degree of importance and calling Witten "relatively famous", amuzing. Also, fourth author because we publish using alphabetical order.
ReplyDelete"IMHO most LCDM folks are stringers and SUSY advocates."
ReplyDeleteWhatever gave you that idea?
"Also, fourth author because we publish using alphabetical order."
ReplyDeleteWho is "we"? It certainly isn't the norm in astrophysics to publish in alphabetical order. Maybe Witten is fourth author because the order is alphabetical, OK. My comment was not a slur at Witten, but rather at the tendency to drop famous names. Why mention any of the authors at all? Or if so, mention them all, or "first author et al." as when citing?
Witten is not an astrophysicist, so it is no surprise that Tremaine and Ostriker (two of the most famous astrophysicists there are) are more famous than Witten among astrophysicists. No, fame doesn't necessary correlate with degree of importance, but I was commenting on fame (since I wondered why only Witten's name was mentioned), not on importance.
Phillip, in theoretical particle physics papers, usually the author list is always alphabetical (unlike
ReplyDeleteastro papers)
Here the author list consists of 3 astrophysicists+ 1 particle physicist. So don't know what criterion was used.
Phillip, I think Witten is equally well known among astrophysicists.
ReplyDeleteHe proposed an explosion model for galaxy formation with Ostriker in 80s, worked
on strange quark stars, dark energy, proposed detection for dark matter detection, etc.
In one of Wittens less known papers, he basically pioneered the physics of galactic halo neutrino detection. So yea, I'd say he's pretty famous in astrophysics as well.
ReplyDeleteno sign of my last three comments. One was just a question, Your comment-rules were abided, your good name was not derided, so wot gives?
ReplyDeletepiein,
ReplyDeleteI haven't posted your comment because it starts with a string of several hundred capital letters (mostly Ns and Zs).
Not sure what you did, but you might want to repost that. I didn't post another one because it contains wrong statements about cosmology that I don't want to confuse other readers. Best,
B.
I may be missing it but I don't understand how MOND-type theories would explain observations of the Bullet Cluster. Maybe they would dispute the interpretation of the evidence but I thought it was claimed at 8σ significance that modification of gravity alone could not account for the measurements.
ReplyDeleteThanks,
Mike
Michael,
ReplyDeletePaper's here, what more are you asking for? Don't know what you read but I doubt your statement is correct.
Michael, I think the Bullet cluster idea as THE evidence for dark matter is very much oversold idea ( for example things like 8 sigma etc). As Sabine said, you should the paper mentioned and then decide. also there are counterexamples to Bullet Cluster such as Trainwreck cluster, which again no one talks about.
ReplyDeleteThe question is, is Moffat gravity a MOND-type theory? The paper is about MOG. There might be some confusion here, in that other "modified-gravity" theories might be ruled out, perhaps including MOND, but not MOG.
ReplyDelete(One also has to be careful also when some paper has a discrepancy of a factor of 2 or 3 between theory and observations and this is touted as agreement while the same factor of 2 or 3 is considered a dismal failure for MOND.)
Moffat gravity has MOND as a limit. MOND isn't as universally applicable as MOG for the same reason Newtonian gravity isn't as universally applicable as general relativity. Hence, complaining that MOND doesn't fit this or that cluster is entirely pointless without asking first whether it even applies in that limit.
ReplyDeleteAnd, yes, as Shantanu says, the Bullett cluster is oversold. It's an appealingly simple explanation that goes well in the popular science media, but it's not as clear cut as it's been portrayed. My understanding is that some clusters are hard to fit both with modified gravity and LambdaCDM, and maybe that shouldn't be so surprising. What we observe today depends on the history of these systems, and exactly what all these galaxies did over the course of billion years is difficult to model.
ReplyDeleteShantanu, thanks for that additional reference.
ReplyDeleteAccording to Mannheim, "solar system phenomenology is left intact", as he is describing in https://arxiv.org/abs/1610.08907.
More problematic seems to be the quantum version of Confirmal Gravity (if standard quantum theory is applied) due to ghost states. But this should not really be an argument with respect to this dark matter discussion, since (at least to my knowledge) neither MOND nor MOG intend to say anything about quantum gravity. Even GR (which is the basis of LCDM) is problematic with quantization.
So, why not taking Confirmal Gravity more serious in explaining galactic (and solar system) observations? Only 4 parameters to fit well a lot of rotation curves is not a bad job.
The Event Horizon Telescope will help in discarding some MOG theories and give a strong test for GR. Any MOG theory that survives this test will not only be the right theory to solve the galaxy rotation curve problem but will certainly point the way to QG.
ReplyDeleteStuart,
ReplyDeleteYes, I wrote about this here.
Thanks for the link. I see that the Moffat version of MOG is likely to fail because on their website the EHT folks report that they have observed a fuzzed version of the shadow which is already 30% less than that predicted by GR .
ReplyDeleteAvi Leob http:// www.nature.com/news/good-data-are-not-enough-1.20906 would agree with you and Moffat in exploring other interpretations of astrophysical data rather than try to filter it in favor of LCDM
One has to be a Bohemian at heart in order to look at the universe in such a way? It has to be written in the CMB data in order for such theoretical discussions to be determinant?
ReplyDeleteI haven't posted your comment because it starts with a string of several hundred capital letters (mostly Ns and Zs).
ReplyDeleteYou don't speak NZ?
Not sure what you did, but you might want to repost that.
I don't know either. Could be fell asleep. I apologize for that. Also my appreciation of your being so relaxed about it.
I didn't post another one because it contains wrong statements about cosmology that I don't want to confuse other readers
That could've been a couple of different things. If you mean my comment about the correlations you raised being connected with redshift periodicity, it's just that the majority of the underlying discoveries of those correlations is the same fella that, who is also the originator of the periodicity observation.
I don't know where the line is drawn for qualifying as a 'wrong statement in cosmology'. Is that reasonable when concerning work carried out by excellent scientists/astronomers that the mainstream chooses to ignore?
If on the other hand you mean my comment about the magnitude/velocity correlation - I did get that wrong in that I misattributed what you were talking about to the original magnitude/velocity observations back circa 1970. Apologies for that as well. p.s. My comment was reasonable given that context
Thanks for being so cool Doc Hossenfelder!
Xkcd chimes in
ReplyDeletehttp://xkcd.com/1758/