If you ask a person on the street, “how do you go about looking for supersymmetry?”, that person will probably cross the street quickly. But if you ask this question on the street at CERN, the laboratory which runs the Large Hadron Collider (LHC), you’ll probably get an answer, of the following form: “Look for a surprising number of collisions with Jets and Missing Energy.”
This answer might cause you yourself to cross the street quickly. But it’s not so impenetrable; it just needs a little translation. What it means is this:
You should look for an unexpectedly large number of proton-proton collisions that show signs of both (a) quarks, anti-quarks or gluons (particles that are found inside protons and other hadrons) flying out of the collision with very high energy, as though shot from a gun (and creating sprays of particles, called “jets”), and (b) undetectable particles flying off invisibly, carrying off lots of momentum and energy.
The purpose of this article is to explain to you why people give this answer, and what its strengths and weaknesses are.
You may want to have read this article on supersymmetry first. It explains what supersymmetry is and what it predicts as far as new particles. Summarizing it briefly: for every type of particle that we know about in nature, supersymmetry requires one or two additional ones, typically referred to as superpartners by physicists, with similar properties but differing in one respect —
- If the particle we know about already is a boson, the superpartner is a fermion, and vice versa. (You can read here about bosons and fermions, if you like. Or you can ignore this point for now, it isn’t crucial for the current article.)
and for consistency with data, it must be that supersymmetry is hidden in a subtle way, leading to a second difference between particle and partner:
- the superpartner is more massive than the particle we already know about.
In the most popular forms of supersymmetry, the superpartner of each particle we know is just heavy enough to be out of reach of previous experiments but within reach of the Large Hadron Collider.
The reason many physicists believe it likely that the superpartners will lie in range of the Large Hadron Collider is that they believe that supersymmetry can serve as the solution to a puzzle known as the hierarchy problem. If the superpartners are much heavier, then the solution to the hierarchy problem must lie elsewhere.
Let us suppose for now that these physicists are right… why should we look for collisions that have multiple jets (i.e. signs of high-energy quarks/antiquarks/gluons) and lots of missing energy (i.e. signs of invisible particles?)
Where does the answer “Jets And Missing Energy” come from?
Well, let me first tell you what these physicists have in their minds, and then I’ll tell you how it got there.
This is what they are thinking:
Since the proton is made from quarks, anti-quarks and gluons, which are affected by the strong nuclear force, the easiest superpartners to produce in the proton-proton collisions at the LHC are their superpartners: squarks, anti-squarks and gluinos. For example (see Figures 2 and 3), in a proton-proton collision, two up-quarks might collide and form two up-squarks.
What would happen next? Like most particles, squarks would decay. Decay to what? In many variants of supersymmetry, squarks decay to a quark, plus another superpartner, called a neutralino (a mixture of the superpartners of the photon, Z, and Higgs particles.) The quarks carry a lot of energy and turn into jets, while the neutralinos zip through the detectors without leaving any observable signal. What we will see, therefore, is two high-energy jets, one from each of the two quarks, and signs that they are recoiling against something invisible and undetected.
The collision itself, with production and decay of the squarks, is shown in Fig. 3. The jets and neutralinos that rush out from the collision point are shown in Fig. 4. And what the detector actually detects — the only information that scientists get in their data — is Fig. 5.
The obvious imbalance, shown in Fig. 5, where a lot of stuff is heading up and to the right but nothing is seen heading down and to the left, is for unfortunate historical reasons and shorthand called “missing energy”. (It is actually “missing momentum in the directions perpendicular to the colliding beams” — a mouthful that partly explains the use of shorthand.)
If instead it is gluinos that are produced in pairs, the situation is only slightly different. Typically each of the two gluinos decays to a quark, an anti-quark and a neutralino, so it is again true that the detectors will see jets (four, in this case) along with lots of missing “energy” from the two neutralinos.
That’s the vision passing through the heads of these physicists when they answer your question about how to find supersymmetry. To comprehend where it comes from requires us to explore the underlying assumptions that go into it.
The Assumptions that Lie Behind the Answer “Jets And Missing Energy”
And that’s the logical journey we’re going to undertake next — illustrated in Figure 6 down below. At the end of our tour, you’ll be able to judge for yourself, to a degree, the strengths and weaknesses of this answer to your original question.
The logic involves three main assumptions.
Assumption 1: we assume there is an additional principle of nature, not required by supersymmetry itself, which states that in any physical process, the number of superpartners can only change by an even number. (The technical name for this is conservation of R-parity, which I tell you not because the name matters but because you may see this term used elsewhere; and I’ll use it below.)
Why do theorists impose this criterion? Without Assumption 1 supersymmetry would predict new forces among matter particles, and typically they would make protons quickly decay. That would be in conflict with data. The proton is very stable (thankfully — even a rather slow rate of proton decay would kill us, and melt the earth, and so on…) You can take a vat full of a billion trillion trillion protons and wait for ten years, and you will not see a single proton decay. (Yes, people tried this! You need 180,000 tons of water.) So without Assumption 1, supersymmetry (and we) would be dead on arrival.
But if Assumption 1 is true — if R-parity is conserved — those new forces are forbidden. Supersymmetry plus R-parity conservation predicts a very, very long-lived proton, consistent (in favorable circumstances) with data.
Note that this requirement of the conservation of R-parity is not imposed because supersymmetry requires it, or on the basis of some theoretical principle. It is added because consistency with data requires it. That said, it is a perfectly reasonable requirement from the theoretical point of view.
Assumption 2: of all the superparticles in nature, the lightest one is a partner of a particle we’ve discovered already, or of a Higgs particle, and therefore it is one of the superpartners appearing in Figure 1, at the top of this webpage: a gluino, squark, charged slepton, sneutrino, chargino or neutralino.
One could certainly question this assumption. For one thing, if supersymmetry is true, then the graviton (the force carrier of gravity) has a superpartner too, called the gravitino — and I didn’t put that in Figure 1. How heavy is the gravitino? We don’t know. In some variants of supersymmetry it is about as heavy as the heaviest superpartners shown in Fig. 1, the squarks and gluinos. In other variants it is quite a bit lighter, and could even be lighter than an electron! That would violate Assumption 2.
Or there might be particles in nature that have rather small masses and that we don’t know about yet because they are very difficult to produce or detect — particles that are not affected by any of the three forces shown in Figure 1, the electromagnetic force or the weak and strong nuclear forces. Such particles are typically called “hidden”, because of how hard they are to produce even if they are very lightweight. (If there are several types of hidden particles, they are often collectively called a “hidden sector”.) Now, these particles have superpartners too, if supersymmetry is true — as mentioned in this article on supersymmetry, supersymmetry is really a symmetry of space and time, so any type of particle that travels in space and time must have superpartners. And if any of these superpartners are lighter than the lightest superpartner shown in Figure 1, well, then Assumption 2 is wrong.
Assumption 2 is not required by any experimental data. The best theoretical arguments against hidden particles suggest that nature is most likely to be simple and elegant, and since hidden particles are extra baggage, they are unlikely. (Whether you are convinced by this argument is a matter of taste.) And the best argument against a light gravitino is that stable gravitinos can cause various problems during the Big Bang. There’s another argument in favor of Assumption 2, having to do with the lightest superpartner being able to serve as the dark matter of the universe, but to understand it we’ll need to understand a few of the various consequences, so let’s hold off on that for the moment.
Assumption 3: the superpartners that feel the strong-nuclear force — squarks, anti-squarks, and gluinos — are on the heavy side, quite a bit heavier than the other superpartners, though not so heavy that they aren’t produced often at the LHC.
This is a squishier assumption than the last two — what exactly do heavy and often mean? Rather than discuss that here, let me simply say that in many, many variants of supersymmetry this turns out to be true. Theoretical calculations do show that in many different scenarios, those superpartners affected by the strong nuclear force end up heavier than most of those that aren’t. But again, it is not always the case.
Now what follows from these assumptions? There are a number of very important consequences that are important to recognize; you can use Figure 6 to keep track.
Assumption 1 has three crucial implications:
- If you start with no superpartners (as you do when two protons collide), and you produce superpartners in the collision, you must produce at least two of them. You can’t start with zero superpartners and end up with one.
- If you have a superpartner sitting around and it decays, there must be at least one superpartner (possibly three or five, but it turns out almost always just one) among the particles produced in the decay. You can’t start with one superpartner and end up with zero.
- The lightest superpartner cannot decay — it is a stable particle — because particles can only decay to particles that are lighter than they are, and for the lightest superpartner to decay would mean one superpartner would turn into zero superpartners.
Remarkable! supersymmetry plus R-parity conservation implies an as-yet-undiscovered stable particle — the lightest superpartner (often written LSP). What properties could this particle have?
Suppose this type of particle were affected by the electromagnetic force or by the strong nuclear force. Then (i) many such particles would have been created in the early universe during the Big Bang; (ii) they would have altered the abundance of various elements, such as lithium, during the Big Bang, so that these abundances would be in conflict with what we observe today, and (iii) they would still be floating around the universe, with a few of them hitting the earth, creating exotic atoms that would long ago have been detected in careful searches for new and unusual atoms. Though this merits a longer discussion, the basic conclusion is that any new stable particle must be insensitive to the electromagnetic force and the strong nuclear force.
Given this, what does Assumption 2 imply? The lightest superpartner must be one of the sneutrinos or one of the neutralinos. All of the other superpartners (squarks, sleptons, charginos and gluinos) of the known particles are affected by the electromagnetic or strong nuclear forces. For technical reasons, most (but not all) particle physicists prefer models where a neutralino is the lightest superpartner. [It can make a good candidate for the particles of dark matter! which is a posteriori an argument in favor of Assumption 2.] But even if a sneutrino is the lightest, the argument in favor of looking for jets and missing energy remains roughly the same, with a few adjustments that I’ll skip here…
And finally, Assumption 3 is that it is easy to produce squarks and gluinos, and they are relatively heavy. That means that they blow up with a relatively large amount of energy; when they break apart, the energy and momentum carried by the quarks and neutralinos to which they decay is big. The resulting jets will carry high energy, and the missing energy will be large.
So now I hope you can understand the vision encapsulated in Figures 3, 4 and 5. If supersymmetry is right, the logic goes, we will produce heavy squarks and gluinos; they decay to high-energy quarks and neutralinos; the quarks show up as high-energy jets, which are easily detected, and the presence of the neutralinos, though undetected, is inferred from an imbalance in the momentum of the jets.
So ok, we look, and we either find or we don’t find. Then what?
And therefore, if we see an excess number of collision events with high-energy jets and missing energy, that’s great; maybe we’ve discovered supersymmetry. However, CAUTION-CAUTION-CAUTION-CAUTION: other types of new phenomena can create similar looking events — it will be some time, years probably, and a lot of hard work, before we would start to be confident as to whether we were looking at supersymmetry or something else new that just looks similar to supersymmetry at first glance. Just because you see something like Figure 5 doesn’t mean that it was produced by Figure 3!
But if we don’t see an excess of events like this, does that mean supersymmetry is definitely not a property of nature? Before we leap to draw strong existential conclusions about the universe by interpreting an experimental result, we should ask what might go wrong with the three assumptions I listed above (or a couple of other less central ones I didn’t mention here). I already told you some of the things that might go wrong, and though I won’t go into any more detail about them here, you can see for yourself that the only thing we’ll be able to conclude, if we don’t see events like this, is that
- either supersymmetry is not a property of nature,
- or supersymmetry is a property of nature but something is wrong with one of the three assumptions in Figure 6.
Don’t be surprised to see press articles and statements by some physicists that go a bit too far interpreting the results from the LHC. It takes time to build knowledge, and impatience often leads to mistakes. Personally I think we need to state our assumptions, and check them whenever possible, when making claims about the existence of supersymmetry, or any other essential properties of the universe.
A couple of other ways to look for supersymmetry
Before wrapping up, I should emphasize that although I focused on the most famous way to look for supersymmetry, there are a number of other ways to search that are well-known, and several of them are being pursued. I won’t explain here where they come from [I might do so later, stay tuned] but very common ones include searching for an excess of collisions that contain
- in addition to jets and missing energy, a charged lepton, a charged anti-lepton, or both; or
- even without jets and/or missing energy, a pair of charged leptons or a pair of charged anti-leptons (that is, two particles with the same electric charge), or perhaps even three or four charged leptons and anti-leptons.
The processes in the last set are so rare and remarkable that there are few other processes in nature that can imitate them, which is why, in trying to distinguish them from look-alike backgrounds, it may not even be necessary that there be high-energy jets and/or missing energy in the same collisions. For this reason they are less sensitive to the three assumptions in Figure 6. I’ll be keeping a close eye on searches for those processes.