This post is adopted from a web page I wrote in 2008, before starting this blog. It covers some ground that I guess is now historic about things that were known about WIMPs from their beginnings in the 1980s, and experimental searches therefore. In part, I was just trying to keep track of experimental limits, with updates added as noted since the first writing. This is motivated now by some troll on Twitter trying to gaslight people into believing there were no predictions for WIMPs prior to the discovery of the Higgs boson. Contrary to this assertion, the field had already gone through many generations of predictions, with the theorists moving the goal posts every time a prediction was excluded. I have colleagues involved in WIMP searches that have left that field in disgust at having the goal posts moved on them: what good are the experimental searches if, every time they reach the promised land, they’re simply told the promised land is over the next horizon? You experimentalists just keep your noses to the grindstone, and don’t bother the Big Brains with any inconvenient questions!
We were already very far down this path in 2008 – so far down it, I called it the express elevator to hell, since the predicted interaction cross-section kept decreasing to evade experimental limits. Since that time, theorists have added sideways in mass to their evasion tactics, with some advocating for “light” dark matter (less in mass than the 2 GeV Lee-Weinberg limit for the minimum WIMP mass) while others advocate for undetectably high mass WIMPzillas (because there’s a lot of unexplored if unexpected parameter space at high mass to roam around in before hitting the unitarity bound. Theorists love to go free range.)
These evasion tactics had become ridiculous well before the Higgs was discovered in 2012. Many people don’t seem to have memories that long, so let’s review. Text in normal font was written in 2008; later additions are italicized.
Seeking WIMPs in all the wrong places
This article has been updated many times since it was first written in 2008, at which time we were already many years down the path it describes.
The Need for Dark Matter
Extragalactic systems like spiral galaxies and clusters of galaxies exhibit mass discrepancies. The application of Newton’s Law of Gravity to the observed stars and gas fails to explain the rapid observed motions. This leads to the inference that some form of invisible mass – dark matter – dominates the dynamics of the universe.
If asked what the dark matter is, most scientists working in the field will respond honestly that we have no idea. There are many possible candidates. Some, like MACHOs (Massive Compact Halo Objects, perhaps brown dwarfs) have essentially been ruled out. However, in our heart of hearts there is a huge odds-on favorite: the WIMP.
WIMP stands for Weakly Interacting Massive Particle. This is an entire class of new fundamental particles that emerge from supersymmetry. Supersymmetry (SUSY) is a theoretical notion by which known elementary particles have supersymmetric partner particles. This notion is not part of the highly successful Standard Model of particle physics, but might exist provided that the Higgs boson exists. In the so-called Minimal Supersymmetric Standard Model (MSSM), which was hypothesized to explain the hierarchy problem (i.e., why do the elementary particles have the various masses that they do), the lightest stable supersymmetric particle is the neutralino. This is the WIMP that presumably makes up the dark matter.
2020 update: the Higgs does indeed exist. Unfortunately, it is too normal. That is, it fits perfectly well with the Standard Model without any need for SUSY. Indeed, it is so normal that MSSM is pretty much excluded. One can persist with more complicated theories (as always) but to date SUSY has flunked every experimental test, including the “golden test” of the decay of the Bs meson. Never heard of the golden test? The theorists were all about it until SUSY flunked it; now they never seem to mention it.
Cosmology, meet particle physics
There is a confluence of history in the development of previously distinct fields. The need for cosmological dark matter became clear in the 1980s, the same time that MSSM was hypothesized to solve the hierarchy problem in particle physics. Moreover, it was quickly realized that the cosmological dark matter could not be normal (“baryonic“) matter. New fundamental particles therefore seemed a natural fit.
The cosmic craving for CDM
There are two cosmological reason why we need non-baryonic cold dark matter (CDM):
- The measured density of gravitating mass appears to considerably exceed that in normal matter as constrained by Big Bang Nucleosynthesis (BBN): Ωm = 6 Ωb (so Ωnot baryons = 5 Ωbaryons).
- Gravity is too weak to grow the presently observed structures (e.g., galaxies, clusters, filaments) from the smooth initial condition observed in the cosmic microwave background (CMB) unless something speeds up the process. Extra mass will do this, but it must not interact with the photons of the CMB the way ordinary matter does.
By themselves, either of these arguments are strong. Together, they were compelling enough to launch the CDM paradigm. (Like most scientists of my generation, I certainly bought into it.)
From the astronomical perspective, all that is required is that the dark matter be non-baryonic and dynamically cold. Non-baryonic so that it does not participate in Big Bang Nucleosynthesis or interact with photons (a good way to remain invisible!), and dynamically cold (i.e., slow moving, not relativistic) so that it can clump and form gravitationally bound structures. Many things might satisfy these astronomical requirements. For example, supermassive black holes fit the bill, though they would somehow have to form in the first second of creation in order not to impact BBN.
The WIMP Miracle
From a particle physics perspective, the early universe was a high energy place where energy and mass could switch from one form to the other freely as enshrined in Einstein’s E = mc2. Pairs of particles and their antiparticles could come and go. However, as the universe expands, it cools. As it cools, it loses the energy necessary to create particle pairs. When this happens for a particular particle depends on the mass of the particle – the more mass, the more energy is required, and the earlier that particle-antiparticle pair “freeze out.” After freeze-out, the remaining particle-antiparticle pairs can mutually annihilate, leaving only energy. To avoid this fate, there must either be some asymmetry (apparently there was about one extra proton for every billion proton-antiproton pairs – an asymmetry on which our existence depends even if we don’t yet understand it) or the “cross section” – the probability for interacting – must be so low that particles and their antiparticles go their separate ways without meeting often enough to annihilate completely. This process leaves some relic density that depends on the properties of the particles.
If one asks what relic density is necessary to make up the cosmic dark matter, the cross section that comes out is about that of the weak nuclear force. A particle that interacts through the weak force but not the electromagnetic force will have the about the right relic density. Moreover, it won’t interfere with BBN or the CMB. The WIMPs hypothesized by supersymmetry fit the bill for cosmologists’ CDM. This coincidence of scales – the relic density and the weak force interaction scale – is sometimes referred to as the “WIMP miracle” and was part of the motivation to adopt the WIMP as the leading candidate for cosmological dark matter.
WIMP detection experiments
WIMPs as CDM is a well posed scientific hypothesis subject to experimental verification. From astronomical measurements, we know how much we need in the solar neighborhood – about 0.3 GeV c-2 cm-3. (That means there are a few hundred WIMPs passing through your body at any given moment, depending on the exact mass of the particle.) From particle physics, we know the weak interaction cross section, so can calculate the probability of a WIMP interacting with normal matter. In this respect, WIMPs are very much like neutrinos – they can pass right through solid matter because they do not experience the electromagnetic interactions that make ordinary matter solid. But once in a very rare while, they may come close enough to an atomic nucleus to interact with it via the weak force. This is the signature that can be sought experimentally.
There is a Nobel Prize waiting for whoever discovers the dark matter, so there are now many experiments seeking to do so. Generically, these use very pure samples of some element (like Germanium or Argon or Xenon) to act as targets for the WIMPs making up the dark matter component of our Milky Way Galaxy. The sensitivity required is phenomenal, and many mundane background events (cosmic rays, natural radioactivity, clumsy colleagues dropping beer cans) that might mimic WIMPs must be screened out. For this reason, there is a strong desire to perform these experiments in deep mine shafts where the apparatus can be shielded from the cosmic rays that bombard our planet and other practical nuisances.
The technology development involved in the hunt for WIMPs is amazing. The experimentalists have accomplished phenomenal things in the hunt for dark matter. That they have so far failed to detect it should give pause to any thinking person aquainted with the history, techniques, and successes of particle physics. This failure is both a surprise and disappointment to those who understand modern cosmology. It should not come as a surprise to anyone familiar with the dynamical evidence for – and against – dark matter.
Searches for WIMPs are proceeding apace. The sensitivity of these experiments is increasing at an accelerating rate. They already provide important constraints – see the figure:
Searching for WIMPs
April 2011 update: XENON100 sees nada. Note how the “expected” region continues to retreat downward in cross section as experiments exclude the previous sweet spots in this parameter. This is the express elevator to hell (see below).
September 2011 update: CREST-II claims a detection. Unfortunately, their positive result violates limits imposed by several other experiments, including XENON100. Somebody is doing their false event rejection wrong.
July 2012 update: XENON100 still seeing squat. Note that the “head” of the most probable (blue) region in the figure above is now excluded.
It is interesting to compare the time sequence of their results: first | run 8 | run 10.
November 2013 update: LUX sees nothing and excludes the various claims for detections of light dark matter (see inset). This exclusion of light dark matter appears to be highly significant as the very recent prediction was for about dozen of detections per month, which should have added up to an easy detection rather than the observed absence of events in excess of the expected background. Note also that the new exclusion boundary cuts deeply into the region predicted for traditional heavy (~ 100 GeV) WIMPs by Buchmuelleur et al. as depicted by Xenon100. The Buchmuelleur et al. “prediction” is already a downscaling from the bulk of probability predicted by Trotta et al. (2008 – the blue region in the figure above). This perpetual adjustment of the expectation for the WIMP cross-section is precisely the dodgy moving of the goal posts that prompted me to first write this web page years ago.
May 2014: “Crunch time” for dark matter comes and goes.
July 2016 update: PandaX sees nada.
August 2016 update: LUX continues to see nada. The minimum of their exclusion line now reaches the bottom axis of the 2009 plot (above the line, with the now-excluded blue blob). The “predicted” WIMP (gray area in the plot within this section) appears to have migrated to higher mass in addition to the downward migration of the cross-section. I guess this is the sideways turbolift to evil-Kirk universe hell.
Indeed, the experiments have perhaps been too successful. The original region of cross section-mass parameter space in which WIMPs were expected to reside was excluded years ago. Not easily dissuaded, theorists waved their hands, invoked the Majorana see-saw mechanism, and reduced the interaction probability to safely non-detectable levels. This is the vertical separation of the reddish and blue-green regions in the figure.
To quote a particle physicist, “The most appealing possibility – a weak scale dark matter particle interacting with matter via Z-boson exchange – leads to the cross section of order 10-39 cm2 which was excluded back in the ’80s by the first round of dark matter experiments. There exists another natural possibility for WIMP dark matter: a particle interacting via Higgs boson exchange. This would lead to the cross section in the 10-42-10-46 cm2 ballpark (depending on the Higgs mass and on the coupling of dark matter to the Higgs).”From this 2011 Resonaances post
Though set back and discouraged by this theoretical slight of hand (the WIMP “miracle” is now more of a vague coincidence, like seeing an old flame in Grand Central Station but failing to say anything because (a) s/he is way over on another platform and (b) on reflection, you’re not really sure it was him or her after all), experimentallists have been gaining ground on the newly predicted region. If all goes as planned, most of the plausible parameter space will have been explored in a few more years. (I have heard it asserted that “we’ll know what the dark matter is in 5 years” every 5 years for the past two decades. Make that three decades now.)
The express elevator to hell
There is a slight problem with the current predictions for WIMPs. While there is a clear focus point where WIMPs most probably reside (the blue blob in the figure), there is also a long tail to low interaction cross section. If we fail to detect WIMPs when experimental sensitivity encompasses the blob, the presumption will be that we’re just unlucky and WIMPs happen to live in the low-probability tail that is not yet excluded. (Low probability regions tend to seem more reasonable as higher probability regions are rejected and we forget about them.) This is the express elevator to hell. No matter how much time, money, and effort we invest in further experimentation, the answer will always be right around the corner. This process can go on forever.
Is dark matter a falsifiable hypothesis?
The existence of dark matter is an inference, not an experimental fact. Individual candidates for the dark matter can be tested and falsified. For example, it was once reasonable to imagine that innumerable brown dwarfs could be the dark matter. That is no longer true – were there that many brown dwarfs out there, we would have seen them directly by now. The brown dwarf hypothesis has been falsified. WIMPs are falsifiable dark matter candidates – provided we don’t continually revise their interaction probability. If we keep doing this, the hypothesis ceases to have predictive power and is no longer subject to falsification.
The concept of dark matter is not falsifiable. If we exclude one candidate, we are free to make up another one. After WIMPs, the next obvious candidate is axions. Should those be falsified, we invent something else. (Particle physicists love to do this. The literature is littered with half-baked dark matter candidates invented for dubious reasons, often to explain phenomena with obvious astrophysical causes. The ludicrous uproar over the ATIC and PAMELA cosmic ray experiments is a good example.) (Circa 2008, there was a lot of enthusiasm that certain signals detected by cosmic ray experiments were caused by dark matter. These have gone away.)
September 2011 update: Fermi confirms the PAMELA positron excess. Too well for it to be dark matter: there is no upper threshold energy corresponding to the WIMP mass. Apparently these cosmic rays are astrophysical in origin, which comes as no surprise to high energy astrophysicists.
April 2013 update: AMS makes claims to detect dark matter that are so laughably absurd they do not warrant commentary.
September 2016 update: There is no update. People seem to have given up on claiming that there is any sign of dark matter in cosmic rays. There have been claims of dark matter causing signatures in gamma ray data and separately in X-ray data. These never looked credible and went away on a time scale shorter so short that on one occasion, an entire session of a 2014 conference had been planned to discuss a gamma ray signal at 126 GeV as dark matter. I asked the organizers a few months in advance if that was even going to be a thing by the time we met. It wasn’t: every speaker scheduled for that session gave some completely unrelated talk.
November 2019 update: Xenon1T sees no sign of WIMPs. (There is some hint of an excess of electron recoils. These are completely the wrong energy scale to be the signal that this experiment was designed to detect.
2020 comment: I was present at a meeting in 2009 when the predictions of Trotta et al (above, in grey, and higher up, in blue and green) was new and fresh. I was, at that point, already feeling like we’d been led down this garden path more than one too many times. So I explicitly asked about the long tail to low cross-section. I was assured that the probability in that tail was < 2%; we would surely detect the WIMP at somewhere around the favored value (the X in the gray figure). We did not. Essentially all of that predicted parameter space has been excluded, with only a tiny fraction of the 2% tail extending below current limits. Worse, the top border of the Trotta et al prediction was based on the knowledge that the parameter space to higher cross section – where the WIMP was originally predicted to reside – had already been experimentally excluded. So the grey region understates the range of parameter space over which WIMPs were reasonably expected to exist. I’m sure there are people who would like to pretend that the right “prediction” for the WIMP is at still lower cross section. That would be an example of how those who are ignorant (or in denial) of history are doomed to repeat it.
I predict that none the big, expensive WIMP experiments will ever find what they’re looking for. It is past time to admit that the lack of detections is because WIMPs don’t exist. I could be proven wrong by the simple expedient of obtaining a credible WIMP detection. I’m sure there are many bright, ambitious scientists who will take up that challenge. To them I say: after you’ve spent your career at the bottom of a mine shaft with no result to show for it, look up at the sky and remember that I tried to warn you.