It’s well known that all of our evidence for dark matter (and dark energy too, but that’s not the subject here) at the present time is indirect: it comes from observing the gravitational influence of the hypothetical stuff, not from detecting it “directly” (i.e., using some interaction other than gravitational). So it’s natural to ask whether we can do away with dark matter by positing some modification of the behavior of gravity; I’ve certainly wondered that myself.
And it may very well turn out that the behavior of gravity on large scales does not precisely match the prediction of ordinary general relativity. Nevertheless, I think that by now we’ve accumulated enough data to conclude that the universe cannot be explained solely by modifying gravity; there is ample evidence of gravitational forces pointing in directions where there isn’t any (ordinary) “stuff” to create them, leading us to accept the existence of some form of dark matter. About a year ago I put up a post that explained this point of view, and took aim in particular at the popular framework known as MOND.
This led to some good discussion in the comments, and also to a behind-the-scenes email exchange between Rainer Plaga, Stacy McGaugh, and me. It’s a bit of old news, but I thought there would still be some interest in our discussion, so (with permission) I’m posting our emails here. Seeing how the sausage is made, as it were. It’s a bit of a long read, sorry about that.
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Rainer, March 1:
Dear Sean,
I discussed your recent vigorous defense of CDM your blog with Stacy, and he encouraged me to send you my – absolutely objective 😉 – position.
On the one hand I am with you that if Stacy uses terms like “serious fine-tuning problem for LCDM” in his newest paper’s abstract (which are then interpreted by science journalists in the way you exhibit), he had to quantitatively compare the expected properties of galaxies under the assumption of LambdaCDM with his data set. If he wants to criticise an idea he has to deal with the idea not with alternatives to it. Alas, he does not do that in this paper.
On the other hand I strongly disagree out of principle to require statements like: ?of course we have more than sufficient evidence to conclude that dark matter exists, we?re just trying to understand how it works and what else might be going on.? from anybody. Really Sean, this sounds like a caricature of the holy inquisition to me, “philosophers can speculate as long as they accept that the final truth is already known from the holy scriptures ;-)”.
Your statement: “Dark matter is real … there’s no reasonable doubt about the dark matter.” is misleading. Stacy and I of course know that dark matter in the form of massive neutrinos does exist beyond reasonable doubt. But that does not answer a crucial question. Crucial questions are: what flattens the rotation curves in galaxies? What creates the third CMB peak? CDM, MOND or something else?
In my opinion the final verdict on these questions is not in, yet. Allow me to argue why your top 3 arguments for the existence of CDM do not convince me, perhaps yet.
1. “MOND is ugly”: The alternative is not “theory for MOND” vs. GR but “theory for MOND” vs. GR + “theory for CDM particle”. The number of exhibited equations then becomes similar. How do you know that TeVeS is uglier than the “theory for CDM particle”?
2. “Clusters require DM anyway” If one could make a case that they require nonbaryonic cold dark matter, I would consider the case settled in favour of CDM. However, the dark matter required for MOND in clusters might be the ca. 40% fraction of baryonic matter that we anyway know is currently missing in clusters (even in LCDM). Do we agree? How can the argument be clinching then?
3. Your strongest argument is the one from the CMB. But still, replacing “MOND” with “CDM”, couldn’t your statement:
“Can some clever theorist tweak things so that there?s a MOND version that actually fits? Probably. Or we could just accept what the data are telling us.”
be used just as well to comment on the well known problems of CDM to reproduce the detailed properties of galaxies?
Wouldn’t this be a great topic for another “great debate” a la Shapley/Curtis 1920 between u and Stacy? In that case it turned out both were partly right and wrong, my personal bet: it would be the same this time ;-).
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Sean, March 1:
Hi Rainer–
Ten years ago, it was perfectly respectable to speculate that there was no such thing as dark matter, just a modification of gravity. (It couldn’t have been MOND alone, which was ruled out by clusters, but it could have been some more elaborate modification.) That’s no longer true. The Bulltet Cluster and the CMB both provide straightforward evidence that there is gravity pointing in the direction of something other than the ordinary matter. The source for that gravity is “dark matter.” It could be simple, like an axion or a thermal relic, or it could be quite baroque, like TeVeS + sprinkles of other dark matter as required, but it’s definitely there.
If people want to contemplate that there is dark matter and also a modification of gravity, that’s fine. If people want to point to features of galaxy/cluster phenomenology and say that these features must be explained, that’s absolutely fine. But if people want to cling to the possibility that dark matter doesn’t exist, that’s not being appropriately cautious, it’s just ignoring the data, and it’s a disservice to the public to pretend otherwise.
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Rainer, March 2:
Dear Sean,
I do not fully understand your argument: do you argue that the bullet cluster proves that _nonbaryonic_ DM exists? To me Stacy’s argument – that MOND might work only with the baryonic cluster DM which is an additional problem even within LCDM – cannot be currently excluded (see 2. in my previous e-mail). Do you disagree with his argument, and if yes, why?
For your convenience let me summarize Stacy’s general argument in my own words (Stacy please protest if I misrepresent it):
a. even within LCDM generally uncontested facts are that in clusters of the size of the bullet cluster (< 10(13) M_sun):
1. ca. 50% of the cluster’s _baryonic_ matter is probably in some invisible form
2. the hot gas is a minor component of the total baryonic matter (see e.g. fig.1 here: http://arxiv.org/abs/1007.1980)
b. suppose that this baryonic cluster DM is in some non-collisional form (e.g. jupiters). Then a.1. would quantitatively explain MOND’s missing cluster DM and a.2. the observational fact that the bullet’s cluster mass is concentrated on the galaxies and not the hot gas.
It is somewhat paradoxical, but seems clear: if you want to rule out MOND you have to deal with its details, if Stacy wants to rule out CDM he has to deal with its details. Neither of you guys is really doing this, and I can understand why: both of you would feel you are wasting time on a wrong concept. But you would not ;-).
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Sean, March 2:
Hi Rainer–
We know how much baryonic matter there is from BBN. It’s not enough to explain the Bullet Cluster or the CMB, even with MOND. Not to mention that you would have to come up with some way to turn the large majority of baryonic matter into some collisionless form. (The paper you just cited says ” the baryons are not missing, they are simply located in cluster outskirts” right there in the abstract.)
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Rainer, March 2:
Hi Sean,
We know how much baryonic matter there is from BBN. It’s not enough to explain the Bullet Cluster or the CMB, even with MOND.
They claim ca. a factor 2 more dark baryonic matter than seen is needed in the clusters. What problem would that pose with BBN? (Don’t forget that the baryonic matter/CDM ratios derived from LCDM in clusters are meaningless if MOND were the answer).
Not to mention that you would have to come up with some way to turn the large majority of baryonic matter into some collisionless form.
Yes, this would need some ad-hoc gastrophysics to produce enormous amounts of e.g. jupiters especially in the cluster centre. Not nice, but not impossible, cooling flows etc… But if all that were true, the bullet cluster would be OK.
(The paper you just cited says ” the baryons are not missing, they are simply located in cluster outskirts” right there in the abstract.)
But that’s exactly what is needed also for MOND: the dark baryons are really hiding somewhere… They are not claiming a detection of these baryons! But let us take a step back on this paper:
What it discusses is the fact that clusters need some dark baryonic matter even in LCDM, ca. 30% of the baryonic matter is apparently unseen. This was unexpected, some gastrophysics will be needed to explain it. (They mention “AGN feedack” and stuff…)
MOND’s problem is more severe, ca. 70% of the baryonic mater would apparently be unseen in the central parts of the clusters. This was unexpected some gastrophysics will be needed to explain it.
Sorry, Sean, this seems like an open problem to me both for LCDM and MOND, admittedly a bigger one for MOND (but then clusters are their worst problem…), but not the ultraclean evidence for CDM that you are claiming…
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Stacy, March 2:
OK, I think at least we all agree that BBN tells us the baryon density of the universe. Lets deal with one thing at a time, the dark matter in clusters. If I understand you, you are saying MOND is falsified because there is dark matter in clusters. Rainer is suggesting that a logical way out of this is if the excess mass in clusters is in some dark, baryonic, collisionless form. I agree it is tough to imagine what that would be (and have consistently said as much) but I am not willing to grant that I know it to be impossible. So the real leap to falsify MOND is to say that the dark mass in clusters is not just dark baryons, but WIMPs (or whatever non-baryonic particles compose CDM). And that follows how? Because Omega_m > Omega_b?
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Sean, March 3:
MOND without non-baryonic DM is falsified by clusters, because you can’t fit them with the baryons implied by BBN regardless of what form they take. That’s admitted by most people, e.g. Sanders’ paper.
More interesting is the question of whether you could get around the need for non-baryonic DM with some other theory of modified gravity. The Bullet Cluster and CMB, again to most people, imply not. Could you wriggle out of that conclusion by combining some new as-yet-unformulated modification of gravity with a huge population of mysterious intergalactic Jupiters? No, because you would still be completely wrong on the CMB. It’s time to accept what the data are telling us and move on.
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Stacy, March 3:
MOND without non-baryonic DM is falsified by clusters, because you can’t fit them with the baryons implied by BBN regardless of what form they take. That’s admitted by most people, e.g. Sanders’ paper.
Ah. I thought this was the conceptual error you were making. Clusters you certainly could fit just with baryons. They’re rare systems. If that is the only place we need dark baryons, then do the integrals. You can satisfy the residual mass discrepancy in clusters in MOND without making much dent in the BBN missing baryon budget.
Do I *like* such a solution? Certainly not. Neither do I like that fact that clusters are the only systems that come close to having the right baryon content in LCDM. Whay are galaxies missing more than half of their baryons? Dwarfs > 90%? I can imagine how this might happen, but the solutions are comparably contrived. The more basic point is that I am not willing to condemn a theory for needing some dark baryons if its competitor also needs dark baryons.
More interesting is the question of whether you could get around the need for non-baryonic DM with some other theory of modified gravity. The Bullet Cluster and CMB, again to most people, imply not. Could you wriggle out of that conclusion by combining some new as-yet-unformulated modification of gravity with a huge population of mysterious intergalactic Jupiters? No, because you would still be completely wrong on the CMB. It’s time to accept what the data are telling us and move on.
The CMB is really interesting. I correctly predicted the amplitude of the second peak (a prediction that is still quantitatively correct) by making the ansatz that there was whatever generally covariant theory might grow out of MOND looked just like GR in the early universe. Obviously that has to change later in order to grow structure, but at least it gives some proxy for what MOND might do with the CMB. At the time, I discussed some of the ways in which this would inevitably fail.
The response initially was that MOND itself made no prediction for the CMB, therefore we should disregard the chance success of this prediction. Now you want to treat the low third peak as an absolute prediction of MOND. You can’t have it both ways. Which is it?
A low third peak would have falsified LCDM. It survives that test. That does not automatically falisify MOND. It just means that the relativistic parent theory (whatever that might be – it is not obvious to me it has to be TeVeS) has to have a net forcing term a la CDM. Does that seem reasonable to me? No, and (as I said with the ultrafaint dwarfs) I too was ready to write off MOND on this point. But Skordis & Ferreira showed that the scalar field in TeVeS might have just such an effect. So I can not, in good conscience, say it is impossible.
You should not accuse me of ignoring data. I have written papers on these subjects. Indeed, one of the things that surprised and impressed me about MOND, when I first got over my initial revulsion and started to look into it, was what a great breadth and wealth of data it did quite in explaining. From the tone of your statements, I imagine you have no idea what I’m talking about. You really ought to check your facts before making ignorant statements to the effect that “MOND only does rotation curves.”
Indeed, you yourself appear to be ignoring facts. Why do any MOND predictions come true? Let’s suppose it is only true that all MOND does is fit rotation curves. That demands an explanation – one you nowhere attempt to provide. Your reasoning appears to boil down to “We’re sure that CDM exists, so somehow it must work out.” Well, I’ve tried – very hard – to see how it could work out. It aint easy. I won’t say it is impossible. But it is as absurd as some of the above dodges are with MOND. Dark matter in galaxies is like epicycles – you can fit anything you like, but it doesn’t explain why a simple formula does better.
You may find it hard to believe, but I started from exactly the same perspective as you. I am far more comfortable with CDM than with MOND. I will breathe a great sigh of relief if and when WIMPs are detected in the laboratory. Then we’ll know the answer, and we won’t have to have these bitter debates. However, I am not being unreasonable in holding the theory to a high standard of proof. If you want to convince me that, for sure, the universe is filled with some till-now hypothetical particle from a hypothetical dark sector outside of the Standard Model of particle physics, then show me a piece. Until then, you are over-reaching.
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Sean, March 3:
You can’t just wave your hands and say that a mysterious “forcing term” will help explain the CMB. If there is no non-baryonic dark matter, there is no way that even-numbered peaks can be different from odd-numbered peaks; the configuration of baryons is precisely analogous. You can mimic the situation in TeVeS (although the numbers don’t seem to work out) because you’ve introduced an independently propagating scalar degree of freedom whose energy density doesn’t follow the baryons. You can give that scalar whatever name you like, but it is “non-baryonic dark matter.” A particularly contrived version, but that’s what it is.
You can’t explain the third peak without a source for gravity that propagates independently of the baryons.
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Rainer, March 3:
MOND without non-baryonic DM is falsified by clusters, because you can’t fit them with the baryons implied by BBN regardless of what form they take.
Why is that? I just don’t get it, and am very open to be persuaded. 90% of all cosmic baryons are presently undetected, right? Only a fraction of the baryonic matter we see directly is in clusters (O(a few percent), let’s say 10%) So why can’t a small fraction, say O(2%), of all the cosmic dark baryons be in the form of e.g. jupiters in the central parts of clusters? They and stars would then dominate the cluster mass and be dissipationless —> no problem with the bullet cluster in MOND.
That’s admitted by most people, e.g. Sanders’ paper.
Where? In http://arxiv.org/abs/astro-ph/0703590 he states about cluster dark matter in MOND: “For example, there are more than enough undetected baryons to make up the missing dark component; they need only be present in some non-dissipative form which is difficult to observe.”
He also likes massive neutrinos, but not to the exclusion of baryonic dark matter.
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Stacy, March 4:
Hi Sean,
OK, now we are discussing science again.
I take your point about the CMB very seriously. It seems to me that you are putting a lot of weight on the third peak, which is not all THAT well constrained. WMAP really has to scrape to get there, so the result is dominated by the systematics of PSF modeling. I presume they’ve done that right, but there are double exponential corrections involved in subtracting the foreground and then getting back to the cosmic signal, so they don’t have to go far wrong to make a bad mistake with the third peak. Presumably PLANCK will clarify this soon, though a glance at their first release images does not provide a lot of confidence about the foreground MW masks that WMAP used. I also wonder, given the visceral reaction you and others have at any suggestion that LCDM might be questionsed, if the PLANCK team would let themselves admit a low third peak even if the saw it.
For now, we have an apparently clear detection of a high third peak in WMAP, and we need to explain the data we have rather than the data we hope soon to have. And honestly, I expect the most likely outcome to be a confirmation of WMAP, with only minor tweaks. So we have to understand the third peak along with clusters and rotation curves and dwarf spheroidals and everything else.
I freely admit that I don’t know how to make the third peak high. I also don’t know that a high-ish thrid peak can’t be obtained in a more general theory. I agree with your point that pure baryons shouldn’t do that – the vector is wrong, as you say. I’m not even convinced TeVeS can do it. But lots of theories (not just MOND-inspired ones) invoke scalar fields, so I can’t exclude the possibility.
I also agree that this is contrived. But we are WAY into contrivance with LCDM, a point I believe you’ve made yourself on occassion. We’ve just gotten familiar with the contrived parts so that they no longer bother us. That doesn’t make them any less contrived.
You make the point that the scalar field solution in TeVeS is just a contrived form of non-baryonic dark matter. But even in pure GR we could use some form of non-baryonic dark matter that gives us the MOND phenomenology. Why not consider an effect due to the physical nature of the particles? Until we detect WIMPs, surely you at least agree that we don’t really know what the dark matter is?
I know everybody invokes feedback to “fix” galaxies, but those models are just as contrived. Actually, they are considerably more contrived, as they inevitably require many more parameters, and those parameters are simply tuned to match observations. Any competent theorist can tune any model to fit a given set of data.
I must have said this to you before, but I will say it again. The MOND formula provides an apparently correct description of the effective force law in galaxies. How does the dark matter “know” to arrange itself just so as to look like MOND? If it manages this trick in galaxies, why not in the solar system? How would we know that the solar system isn’t really run by an inverse-cube force law, but there is dark matter arranged just so as to make it look like an inverse-square law?
Could anything be more contrived?
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Sean, March 6:
Hi Stacy–
I’m not sure what you are saying about the third peak in the CMB. We agree that “pure baryons shouldn’t do that.” I can only think of three possibilities.
(1) There is some sort of source for gravity other than baryons.
(2) There is a modification of gravity that doesn’t include new sources, but also doesn’t respond directly to where the sources actually are.
(3) The data aren’t good enough to say that the odd-numbered peaks are boosted relative to what we would expect from damped oscillations of baryons alone.
If it’s (1), then that’s non-baryonic dark matter and we should just admit it. I think that (2) is physically implausible, and as far as I know nobody has suggested otherwise. And I think that the time is past when anyone could credibly hang on to (3). Here’s a relatively recent figure (2 years ago) from Ned Wright’s web site.
Am I missing a possibility, or would you buy one of these three?
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Stacy, March 7:
Hi Sean,
I basically agree with the 3 possibilities you list. Indeed, I thought that was pretty much what I said.
You imply that it is hanging on to vain hope to explain the third peak of the CMB by anything other than a new source. I am saying that it is a vain hope to imagine that turning the crank on any number of CDM numerical simulations is ever going to spit out the observed MONDian phenomenology. Just because LCDM works for the CMB does not automatically guarantee that it’ll work in galaxies, any more than MOND’s success in galaxies means it must inevitably succeed as a the basis of a cosmological theory.
There is a very simple empirical result in the data for galaxies that cosmologists have, by and large, simply ignored. The stated excuse is usually something like “well, galaxies are complicated, non-linear structures” and so we should be excused from explaining them. Indeed, in LCDM galaxies probably should be complicated. But they’re not. They’re simple. So simple, the obey a single effective force law. Fitting that with dark matter is like fitting epicylces to planetary orbits. Of course you can do it – you have an infinite number of free parameters. But it don’t make no sense.
I have said for years now that they conclusion you come to depends on how you weigh the evidence. The CMB is an important piece of that evidence. So are rotation curves. It is not obvious to me that the third peak should count 100% and galaxies zero. Yet that is in effect the weighting that lots of people appear to be using.
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Sean, March 8:
Hi Stacy–
I think we’ve reached the end of what needs to be said. You agree with my three possibilities, and you agree (I think) that the CMB data are good enough to draw some conclusions. It comes down to whether you are willing to entertain the possibility that there is a mysterious new force that does not involve any new sources, yet also does not respond directly to where the actual sources are. (And in the process reproduces exactly what we would see if there were CDM.) You may think that is plausible — I, and most people in the field, do not. Therefore, we believe that there is non-baryonic DM, and the question is how it behaves.
You seem to think I am defending LCDM, when I have never mentioned it. I am defending the claim that “non-baryonic dark matter exists.” As I said in the original post, we certainly have to explain the phenomenology of galaxies and clusters, and the right explanation may very well involve a modification of gravity or interesting new physics in the dark sector — both of which I’ve written papers about. Nobody is suggesting that we ignore data from galaxies and clusters. But none of that data straightforwardly implies “non-baryonic dark matter does not exist.” It’s a complicated dynamical problem. The CMB — an enormously simpler system, where everything is in the linear regime — does straightforwardly imply “non-baryonic dark matter exists.” Admitting that will improve our chances for future progress.
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Stacy, March 8:
Yes, we’ve said what we’re going to say. But you still don’t seem to get it. The CMB is simple. It is not enormously simpler. Galaxies are also simple. One must invoke absurdly complex mechanisms to make that happen. The argument against dark matter doing this boils down to fine tuning. I don’t like fine tuning problems, especially when a theory is not otherwise falsifiable (e.g., epicycles). Note that as you claim not to be specifically defending LCDM, I am not specifically defending MOND. There is an empirical phenomenology that constitutes a fine tuning problem for ANY dark matter picture (that does not some how build it in).
Since we can’t explicitly falsify the existence of dark matter, what could be worse than this mother of all fine-tuning problems? I understand the implausibility of what you are saying in the CMB, but you seem to miss the same kind of point in galaxies. I worry that we won’t find WIMPs and keep pursuing other DM candidates indefinitely – how do we know when to stop? How would this be different from another millenium of dark epicycles?
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Rainer, March 18:
Dear disputants,
Thanks for this really informative and nearly polemic free (Stacy please stop blaming your colleagues to construct epicycles ;-)) debate!
To me (and it seems also to Stacy) Sean’s concentration on his main argument, makes his case for some kind of “dark non-baryonic field that enters the stress-energy tensor in GR” quite convincing. It then stands to reason (but is not absolutely necessary) to identify it with a quantum field for some new massive particle.
If I may make Stacy’s main point in my own words: galaxies are observed to be simpler than they would be expected to be: at least a large fraction of them obeys a strange simple MOND rule, which is without a simple plausible motivation in known physics. In addition there are indications that galaxies sometimes behave in ways that they should not in LCDM (tidal dwarves should not contain dark matter but they seem to do).
This reminds one of atoms in classical physics, which were expected to show a very complex behaviour but obeyed strange simple rules, sometimes in contradiction to the known physical laws at the time. The old quantum condition comes to mind as somewhat analogous to MOND’s law of motion. Initially it was attempted to explain these rules within the known concepts, and that was all right and necessary.
But, as quantum mechanics showed, there is _also_ the possibility that strange simple rules for basic objects of the theory are first clues for really new concepts.
Sean, don’t you have at least a little bit of sympathy for this possibility?
I close with following proposal: CDM or MOND? is not a good question. A better question is: are the successes of the MOND rule _perhaps_ a first clue to new concepts which will modify our understanding of the “dark non-baryonic field that enters the stress-energy tensor in GR” in the sense that it is not only a new quantum field within standard QFT?
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Sean, March 18:
Hi Rainer–
Sure, I’m happy to agree with that. In fact, you will find exactly those sentiments way back in my original blog post on the topic. I just think we’re past the point where we can conclude that non-baryonic dark matter exists — what form it takes, how it interacts, and what additional things might be going on, are all crucially important questions. Of course DM faces important challenges from the phenomenology of complex structures, and that should be taken seriously; but no-DM alternatives are ruled out by the data, which should also be taken seriously.
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Stacy, March 19:
Science is dead.
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Stacy, do you have any thoughts on http://arxiv.org/abs/1205.1450 ?
Julianne Delcanton’s point seems to have gotten lost in the noise, so let me say that I think it is the thing that should be addressed most carefully:
The much-celebrated decent fits to a single parameter seen in MOND papers deserve explanation. Whether that explanation involves modified gravity, a new empirical rule found from structure simulations, some sort of (g)astrophysical understanding of galaxy formation, or something to do with solving galactic disk formation is the real open question. All these hypotheses have been placed on the table, but there clearly are problems with taking the “MOND-only” approach that seems to be the bread-and-butter of many of the Milgrom-boosting camp (Disney, Kroupa, McGaugh, and others). The issue of “dark matter”, though informed historically by rotations curves, shows up in so many other places in cosmology and astrophysics that it is irresponsible to claim that galaxies alone push away the WIMP hypothesis and demand a scientific revolution in cosmology.
Or maybe I misinterpret that camp’s perspective.
What I would like to see is a bit less sound and fury about falsifying Lambda-CDM coming from the MOND-boosters and a little more work on what the special acceleration/gravitational potential could mean in terms of detailed look into the state-of-the-art cosmological/galaxy formation theory and observations. That’s why I think Julianne is right on the money here.
I don’t agree with Derek Fox (comment 7) that Popper’s approach is wrong. Popper described the essence, and later others extended the picture. If a theory is verified, especially when it made a highly-constrained prediction, then that gives confidence in that theory. But only until the theory fails a test. It can have had many spectacular successes, they don’t help if it one day gets proven wrong. The support a theory gets by passing a particular test is more a psychological effect, and not a strict logical one. We might prefer the theory because of that success, but this does not prove it to be right, or ‘more right’ than *every* possible (maybe not even imagined) alternative.
When Derek writes “avoiding even the faintest whiff of this attitude should be a high priority for theorists wishing to swim in the mainstream of their science“, I agree with him that one needs to try to falsify one’s theory. But this statement has an implication which he might not have intended. Why at all should it be desirable for a theorist to ‘swim in the mainstream of their science’? This might be interpreted as an ‘either you are with us or you are with the crackpots’ kind of argument. I don’t think it would be science anymore if we aim at agreeing about everything right from the start of the development of a new theory. Yet I see a similar kind of attitude expressed by some colleagues (certainly not in the majority). Do you think it is good scientific practice for a professor to tell a student that he ‘would never hire anybody who has written a paper on MOND’? I don’t think so, but heard exactly this once, as well as many warnings that criticizing the mainstream theory puts your career at a severe risk. Is this still a good advice or is it intimidation? To be honest, when advocates of a theory use such means, I am growing suspicious of their motivations. A good-standing theory should not need this kind of behavior. If you are convinced that the theory you favor is the correct one, there is no need to be afraid of alternative approaches, as you can be confident that they will turn out to be worse than your theory.
As said, Popper’s description was not the final one, there have been several important modifications. Falsification is not as simple as one might imagine, one has to be sure that the falsification itself is a certain one. Scientists seem to prefer to modify favorite theories instead of rejecting them, or they, as Imre Lakatos described, even add a protective belt of auxiliary hypotheses to make sure the theory survives observed anomalies. In addition, if there is no alternative theory readily available, scientists seem to prefer to work with a theory which has been falsified. It is better than nothing, after all. Now this shows why it might become dangerous to discourage research in alternative directions: we might get stuck with a theory having many problems, but the mainstream not willing to give it up because no equally developed alternative is available. In my opinion, we should not discourage non-mainstream ideas, but encourage them. We should avoid focusing all our scientific attention on just one theory. Researching and listening to alternative approaches is important.
Coming back to the question of cold dark matter and Josh’s comment (53): one should look at the broader picture, yes. Currently, more and more cracks open in the standard cold dark matter theory (CDM). In the past few weeks alone there was the Moni-Bidin et al. paper, our work and also a paper by Karachentsev, showing that there is also a factor of 3-4 less dark matter in the local universe than predicted by cosmology. And there are many more known problems without solutions (see the list in Pavel’s paper, for example). The rejection of an alternative theory like MOND does not make the mainstream theory’s problems go away. Pointing out that one theory fails does not put you into the ‘boosting camp’ of a particular alternative. People do not search for dark-matter problems to promote MOND. The problems motivate why alternatives such as MOND are worth looking at.
It might well be that we are witnessing the early stages of what the philosopher Thomas Kuhn described as a scientific revolution. The current situation certainly resembles the structure of science as described by him. Most of the time, we do “normal science”, working in an established paradigm (CDM in this case). But as more and more problems add up, science reaches a crisis from which a new paradigm emerges. It is already becoming more fashionable to at least modify the theory, some cosmologists switch from cold to warm dark matter, for example. We might therefore be approaching this last phase, where new ideas can lead to a jump in understanding. If that is the case, the next years will become very exciting.
Do we really know what gravity is, other than GR models it as warped spacetime? When mass turns to energy, it expands greatly. What happens when energy turns to mass? Would there be a corresponding contraction and gravity is not so much an effect of the existence of mass, but the creation of it?
Consider:http://phys.org/news/2012-04-fermi-gamma-rays-unearth-clues.html
“According to Porter, the new analysis leads to several conclusions. For example, it shows that the density of cosmic rays is higher than anticipated in the outer regions of the galaxy and beyond the central galactic plane. In addition, the total amount of gamma radiation from cosmic ray electrons due to interactions with infrared and visible light – which consist of photons of much lower energy than gamma rays – is larger than previously thought.”
So the missing mass can’t be found, but there is a halo of excess cosmic radiation. So starting on the perimeter of galaxies, down to the core of massive bodies, there is a constant collapse/fusion of energy into ever more dense mass. Wouldn’t this contraction create a corresponding vacuum effect?
That way, the mass being formed is equivalent to the vacuum effect pulling it together, creating the flat rotational curve of galaxies, as the process is uniform.
Bee (#40)– Thanks for the catch, fixed.
Phillip, it’s not really accurate to say that black holes have been ruled out by observation. They have fallen out of favor mainly because most cosmologists don’t realize that the baryon nucleosynthesis ratios depend on density during early inflation, and we have no information about whether inflation expanded at a constant rate or whether it started slower that it ended, in which case there would be sufficient density for primordial IMBHs.
Someone please correct me if I’m mistaken, but I don’t think there is a single observation inconsistent with the 100,000 stellar mass black holes which Frampton has been publishing about for about a decade.
Why do you feel that (weak,strong) lensing does not falsify the notion that there is a large amount of IMBH’s scattered in the galaxy?
Remember what the lensing surveys look for : transit events. Why do you think the black holes are immune to that?
Eric,
Massey, Kitching, and Richard (2010) say:
“There have been extensive and sustained efforts to characterise the number of MACHOs in the halo of the Milky Way, its satellites the Large and Small Magellanic Clouds, and our neighbouring galaxy Andromeda (M31). Even though MACHOs are not visible themselves, whenever one passes in front of a star its gravitational microlensing briefly brightens the star. Since the volume of space along lines of sight that would cause microlensing is tiny, many millions of stars need to be continually monitored. Looking towards 12 million stars in the Magellanic Clouds for 5.7 years, the MACHO survey [306] found only 13–17 microlensing events (and some of these have been challenged as supernovae or variable stars). At 95% confidence, this rules out a model in which all of the Milky Way’s dark matter halo is (uniformly distributed) MACHOs. However, if all events are real, the rate is still ∼ 3 times larger than that expected from a purely stellar population, indicating either that they contribute up to 20% of the Milky Way halo’s mass [307], or a larger fraction of the Magellanic Cloud halo, in less massive bodies [308]. Also looking towards the Magellanic Clouds, the Experience pour la Recherche d’Objets Sombres (EROS) project [309] found only 1 event in 6.7 years of monitoring 7 million stars, compared to the 39 expected were local dark matter composed entirely of 0.6E−7 – 15 M⊙ MACHOs. Looking towards the Magellanic Clouds and the densely populated central bulge of the Milky Way, the Optical Gravitational Lensing Experiment (OGLE) [310, 311, 312] detected only 2 microlensing events in 16 years, and even these events are consistent with self-lensing by stars, rather than MACHOs [313, 310]. The OGLE results conclude that at most 19% of the mass of the Milky Way halo is in objects of more than 0.4 M⊙, and that at most 10% is in objects of 0.01–0.2 M⊙. The POINT-AGAPE experiment [314, 47] observed unresolved (pixel) microlensing in the more distant Andromeda galaxy, and found that at most 20% of its dark matter halo is in 0.5–1.0 M⊙ mass objects (at 95% confidence).”
So that rules out uniformly distributed MACHOs and MACHOs less than 15 M⊙, correct? Frampton’s distribution of black hole dark matter around 1E+5 M⊙ doesn’t even come close to being excluded.
What other lensing results impose constraints?
P.S. Sean, would you please ask your sysadmins to allow <sup> and <sub> tags in comments for super- and sub-scripts?
NASA’s IBEX has established the speed of the Solar System at 83.000 km/hour, 11.000 km/hour (about 12%) slower than thought before.
By the way (@Phillip Helbig, comment 47), the quote of Pavel in the RAS press release was indeed wrong and has been corrected now.
I think that to really rule out a theory, you are going to generally need some sort of laboratory test; in tests of gravitation, the “laboratory” is the Solar System. Can MOND/TeVeS be tested in the Solar System ? It turns out it can, in the special locations where local gravitational accelerations cancel. There is a serious proposal to do this with the LISA Pathfinder, after its primary mission, by using a WSB trajectory to get it from the Earth Sun L1 Lagrange point to where the Earth/Moon/Sun gravity all cancel. The LISA/Pathfinder accelerometers (being used as a gradiometer in this case) should have more than enough sensitivity to either confirm TeVeS, or push it into a very uncomfortable corner of its parameter space, and this test should be doable in this decade.
Basic references :
http://arxiv.org/abs/1001.1303
http://arxiv.org/abs/1107.1075
http://arxiv.org/abs/0912.0710
eric gisse @57 : While the optical depth of being lensed is independent of the mass of the lenses in a MACHO scenario, the duration is not. If the typical lens mass is much less than the Earth’s, the events are typically hours or less, too quick to reliably see (at least, without some Kepler-type space mission), and if it is bigger than ~10^4 Solar masses, the events take longer than we’ve been observing for them (decades or longer). So, microlensing only really constrains MACHOs between those two sizes (and, the actual upper limit is less than 10^4 for existing surveys). See Equation 44 here for the math :
http://relativity.livingreviews.org/open?pubNo=lrr-1998-12&page=articlesu14.html
@56 und 62: Microlensing surveys place tight constraints on the amount of dark matter in compact objects. Primordial black holes are independent of nucleosynthesis, so that is not why they are ruled out. Very massive black holes would also be visible: not necessarily in microlensing surveys, but because of other types of gravitational-lens effects.
By the way, I (the Marshall of # 61 and 62) am not the Marshall of # 8 and #12. I wasn’t aware this didn’t force name uniqueness, so I will expand my name.
On http://arxiv.org/abs/1205.1450 . This constrains TeVeS and a set of similar theories, but does not rule it (or them) out.
To quote from the paper :
“Therefore, the results of the present paper do not rule out TeVeS, but show that its original 2004 formulation by Bekenstein may need to be amended. At present, even its original writing is consistent, although it does need some tuning.”
(I assume that by “original writing” they mean “original version,” but at any rate this does not seem conclusive, one way or the other.)
great success! my technical reply is being marked as spam. now to figure out why…
FUCK. This commenting system ate yet another technical reply and I’m sick and goddamn tired of retyping. Forgot to copy before submitting and poooof! Not sure why WordPress is being such an asshole to me but, hey, WordPress.
I think this is the 5th time on a second day I’ve tried to submit this:
@James:
OGLE I-III, with IV in progress, EROS I and II, MOA, SuperMACHO are examples of microlensing surveys.
The basic problem with black holes as IMBH’s is that it doesn’t make too much sense WRT galactic formation given the fact that galaxies only have one central black hole unless there’s been a merger. Its’ my opinion that black holes were the nuclei that galaxies formed around but that is a bit speculative…
@ Marshall Eubanks:
That particular paragraph isn’t a surprise to me. They’ll just try another form with maybe a few more free parameters all the while arguing it is a serious theory.
That paper really does rule out TeVeS given it nulls out a crucial parameter within the theory tha would distinguish it from other relativistic theories like GR. If they want to play the game of shifting the goalpost then they can go right the hell ahead but they’ll pay for it with zero traction within the community at large.
OK so the OGLE link is being treated as spam. WordPress is stupid. Nice to know why my comments were being silently dropped…
The OGLE link I wanted to share: http://tinyurl.com/bqnofhz
Also @marshall 62, the scaling goes as the square root of the lensing mass. Crossing times are still short for an IMBH even at human scales. The variously above-mentioned surveys have something like 20 years of integrated telescope time put together and if nothing has been found then I personally find it quite hard to believe that a large volume of IMBH’s is an acceptable alternative even without taking into account the various dynamic and optical (from accretion) issues they would generate.
I think we all need some light relief in the form of dark humour. As far as I know, this paper is not a joke: http://www.sciencepub.net/nature/ns0712/05_2012_easy_ns0712_31_32.pdf . Dig the name of the journal: it allows one to say “I have published in [name of journal]”. Let’s be happy that our debate takes place on a higher level.
Phillip Helbig @62 – I actually looked into this around the time the ICRF was being set up.
Suppose you want to constrain black holes with a mass of 1 million Solar masses. You would need about 1 million of these to make up the Galaxy’s missing mass. Suppose they are spread around uniformly out to 100,000 light years, then the mean separation is order 1000 light years, so there might be one about 1000 light years from us. At that distance, the angular size of the Einstein radius is about 3.6 arc sec. With 1000 VLBI sources, the nearest is likely to be about 3.6 degrees away. The deflection at 2.6 deg is 2 mas, easy for VLBI _if you knew where the source was without lensing. Alas, you don’t, and the trouble is that the proper motion is only 0.02 micro as / year, well beyond the ability of current and any likely VLBI. Gaia will have a much higher source density, but of sources with their own proper motions, which will obscure the lensing from IMBH.
So, I don’t think you can rule out IMBH, at least from astrometry.
Phillip Helbig @ 68 – I’ve red The Paper and found it thoroughly entertaining. It would be appreciated if you could point to “papers” of this kind more often – how do you find them?
By the way, I think that if there were anything like 1 million IMBH in the galaxy, we would observe them directly. I don’t think 1 million “milli-quasars” would be easily missed.
Eric, are there any theories of SMBH formation which do not predict a vastly larger number of IMBHs? Charon suggested Lodato & Natarajan (2006) above, but it actually predicts the formation of median 100,000 stellar mass black holes, exactly in line with Frampton’s papers.
Marshall, how long does it take for an IMBH to clear its accretion disk? I’ve read that they can swallow a solar mass in years, not decades, and how often would that kind of an encounter occur? I think most of the million IMBHs would likely be visible for much less than a millionth of the time. Is there any peer reviewed work on this?
I don’t know the SMBH formation theories that well, so I’m just going off my personal intuition and the lack of commensurate evidence.
re: eating time, since we don’t have direct observations of an IMBH, we don’t really know. Besides, it is hard to quantify ‘how long’ because that would depend on how the star got too close. Eg, was it a grazing pass that’s now destroying it or a near-on hit?
I think stellar devouring is less important, observation-wise, than orbital dynamics and accretion of nebulae and background dust which would add a nice localizable noise source in the sky. This times the tens of millions of them that would be needed to fill out an average galaxy’s halo means that odds are one of them would carve a path through a stellar nursey and leave a nice wave as it travels.
Plus there’s the fact that one of those would be a huge gobular cluster unto itself in terms of sheer mass. That would have to make a mess of local orbital dynamics.
Eric, I believe that most of the IMBH candidates in the Milky Way are associated with globular clusters, although there was recently at least one such cluster where an IMBH was ruled out. I wish we had more information about the expected lifetimes of accretion disks from both interstellar media and stars. For a galaxy the size of the Milky Way, you would expect only about a million 100,000 stellar mass black holes if they comprised all dark matter, not tens of millions.
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