However, one thing kept coming up in the show. It also was my overall impression of the book. Did you notice how they kept saying "may," "might," "could," and other wishy washy words like that? It seems to me that String Theory is one possible TOE, out of some larger number of possibilities which we haven't quantified. After someone first noticed some cool aspects of it (similarity of some QM laws with vibrating string equations, the fact that something which looks like a graviton falls out of the equations), they ran into trouble with these "anomalies." Then someone noticed that if we work in ten dimensions, it becomes self-consistent. ST proponents treat this as if it's some fundamental insight, but it could also be viewed as a kludge to the theory to give it a somewhat longer life till we find the next thing wrong with it. Now I think they're up to eleven dimensions. What's next? 42?
I think inserting such qualifiers is essential when discussing science with non-experts. When these guys are chatting with each other they don't do it! Would make the conversation somewhat dreary..
However from your comment I think that perhaps they didnt emphasize that the 3 constraints of
(i) relativity (no FTL signalling)
(ii) positive probabilities (make sure you dont predict something occurs with negative probability!)
(iii) positive energies
actually severely restricts the type of quantum mechanical theory you can devise for a non-pointlike particle. (i.e. These are the postulated ultimate physical restrictions that perhaps they werent making clear when talking about anomolies etc. ) In fact, we've found pretty much only one way of doing it, and that way is the construction we call M/string theory. Within that construction are lots of possible "particular examples" - one of which we hope corresponds to our universe. In a similar way (though not perfectly analogous) there is only one classical mechanics, we need to "fit the observations" to the specifics of the problems we want to tackle using it.
It seems quite possible to me, even likely, that we have a bunch of the brightest minds working on a dead-end path. OTOH, it's the only path we know of at this time.
This has the advantage of keeping them out of my work. ST has had a myriad of extremely useful results in many other areas of physics as well as mathematics, so it'll never be judged a complete waste of time...
Some prominent physicists (one was on the show) complain that ST will never make a testable prediction. From what it looks like to us now, we would need colliders on a scale that they never will be practical to build (and I mean never). I just can't see this panning out in my lifetime.
Personally I think this objection is bunk. If correct, ST in principle predicts things about the big bang that we should be able to observe the consequences of today. It in principle predicts the mass of the electron, which we have already observed. I say in principle, because it has proven too hard to extract such a prediction. However I doubt anyone working in ST genuinely thinks the theory will remain untested until we can build solar system sized colliders...
