Wednesday, November 17, 2004

Theories of Everything

Everybody is talking about the landscape so I should probably also throw in a couple of words. It seems, the lesson from recent progress in understanding string compactifications with N=1 susy is that some people’s hopes for a unique vacuum with four macroscopic directions and SU(3)xSU(2)xU(1) gauge group and matter in the appropriate chiral representations was not fulfilled. It seems, there is not even a small number of N=1 vacuua but rather a number where even the logarithm is larger than some people’s ability to count.

This is quite disappointing for people who were hoping that string theory as the theory of everything would once and for all answer all questions about space-time dimensionality, matter content, masses, coupling constants, mixings etc. There are even people who argue with this new insight string theory lacks any predictability at all.

What I would like to argue is that both these views, the optimistic hope for a unique vacuum and the claim of predictive emptiness of string theory, have unrealistic expectations of a theory of everything.

We now have some centuries experience with more and more unifying and more and more fundamental theories (starting from Newton’s unification of gravity with celestical motions) that we should have learnt the lesson how these things work: There are always two theories, an old one and a new one, or an engeneering and a physical theory if you allow me this pun. The old one often actually consists of several independant subtheories (like the theory that "apples keep falling down" and "planet move on cubic sections") and the new theory in some sense "explains" the old theories.Like there is a simple, local force law corresponding to differential equations that happen to have cubic sections as their solutions.

Another example would be the theory of atomic spectra: Lacking any quantum mechnical model (not even Bohr's theory) one could have just a big book that contains the frequencies of the spectra of all elements (and possibly molecules). That is a theory of the type engeneers like to have: They have big tables with lots and lots of numbers describing for example all possible gears that are on the market with their mechnical properties.

Another example of such a theory is the particle data book. This contains many many numbers that describe out understanding of the standard model. Well, here I am cheating a bit because we believe that most of the numbers (especially all the branchings and all the baryonic data could in principle be computed from QCD etc), but there are still the first couple of pages. You get the idea. Now one might have hoped that once one has a sufficient understanding of string theory in situations with low or even no susy, there would be a unique ground state and similarly, one could have computed all those numbers (like mass of the electron, weak mixing angle, the ud matrix element of the CKM matrix) from string theory. Now the landscape seems to end these hopes.

But why should we have stopped with those microscopic numbers? If there would have been a unique state of string theory, we should be able to compute many more properties of this state (also known as our univers): Why not compute the mass of the earth. Or the number of water molecules in the Atlantic ocean. Or the length of my left index finger. If there is only one state (=one universe), all these numbers should at least in principle be computable from
.


Obviously, this is nonsense and nobody would have believed this in the first place. It might have been a possible scenario but nobody should have been so overoptimistic to expect a unique state of string thoery.

The real difference between the old and the new theory is that what used to be 'external parameters' in the old one (for example parameters of its equations of motion) are properties of the solution/initial conditions of the more fundamental one. This is like Maxewells equations: For all we know, they are the fundamental theory of electromagnetic radiation but nobody would expect to compute from them which song Radio 1 is playing at the moment. The song is just encoded in the initial and boundary conditions for a specific solution to dF=0, d*F=j.

I think, one should (have) expected a similar situation for string theory (or better M-Theory): As a theory of everything it should not have dimensionless parameters in its formulation, but still, there are many solutions to its equations of motion and at least some of the properties of our world (including maybe some of the standard model parameters) are simply properties of a specific solution.

But on the other hand, this does not mean that anything goes and (again in principle) string theory will never make any prediction: Simply take scattering at very very large energies. Those that correspond to distance scales much smaller than our compactification at hand: Than I would expect to see an excitation spectrum typical of strings with the tower of states etc. OK, this might not yet happen at LHC but I am talking in prinicple.

Furthermore, it might be that over all solutions to the string equations of motion not all but only a submanifold (or even only a discretuum) of the macroscopic parameter space is swept out: There are relations. It might be that the mass of the proton is always 612 times the mass of the electron times the number of generations. Who knows? That would clearly be a prediction. It's just at this stage we are not yet powerful enough to make these kinds of predictions.

Even in quantum mechanics, may properties of the emission spectra one is computing with Schrödinger's equation depend on intial and boudary contions: One has to specify for example the charge of the nucleus and the number of electrons before one can predict the energy spectrum. There is no unique solution to Schrödinger's equation but still, QM predicts for example Rydberg's law that you can write the energies as a constant times (1/m -1/n) for small integers m and n. Similar predictions be be possible in string theory even if there are many vacuua.

2 comments:

Anonymous said...

"What I would like to argue is that both these views, the optimistic hope for a unique vacuum and the claim of predictive emptiness of string theory, have unrealistic expectations of a theory of everything."

But you haven't said what you expect from a theory of everything. People used to say that a TOE would tell us the gauge group, solve the hierarchy problem, give the spectrum of elementary particles. That has not happened, and at the moment does not look very likely to happen. Most people also used to say that a TOE would include quantum gravity. Most stringers claim that string theory does include quantum gravity. But no one explains what we should expect from a quantum theory of gravity -- all such discussion revolves around finding a solution for the black hole entropy problem.

So while it is possible that people had unrealistic expectation of a TOE (and therefore of the theory formerly known as string theory), it is very far from clear what the `realistic' expectations might be. And until someone makes a checklist of what a TOE is `realistically' expected to achieve, you will have all sorts of extremist arguments from both camps.

Luboš Motl said...

I think that the landscape people are just keeping on brainwashing everyone else, but the (anthropic) landscape's existence is definitely very far from being a consensus among string theorists.

Andy Strominger says that this landscape business is a fashionable trend that will go away.

Tom Banks emphasizes that we don't know a single controlled non-supersymmetric background, and we don't understand SUSY breaking at the stringy level. It's still not excluded that once these things are understood, there will be a (nearly) unique 4D SUSY breaking vacuum.

Cumrun Vafa is gonna publish a paper with E. Verlinde on the entropic principle, which will contain a very different procedure for calculating the weight of different vacua than the "anthropic" approach.

In my opinion, the flux vacua are only the most active area in canonical string phenomenology, but they are not necessarily the most realistic ones.