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  What are the details around the origin of the string theory?

+ 7 like - 0 dislike
5870 views

It is well-known even among the lay public (thanks to popular books) that string theory first arose in the field of strong interactions where certain scattering amplitudes had properties that could be explained by assuming there were strings lurking around. Unfortunatelly, that's about as far as my knowledge reaches.

Can you explain in detail what kind of objects that show those peculiar stringy properties are and what precisely those properties are?

How did the old "string theory" explain those properties.

Are those explanations still relevant or have they been superseded by modern perspective gained from QCD (which hadn't been yet around at the Veneziano's time)?

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Marek
asked Aug 18, 2011 in General Physics by Marek (635 points) [ no revision ]
retagged Mar 27, 2014 by dimension10
My experimental thesis was using Regge poles to search and explain resonances seen :). Regge poles are still there. Their value as an organizing substructure was undermined when the eightfold way first showed the value of symmetries, and then of course the SU(2)xSU(3)xU(1) success as the standard model erased them from memory . I have always thought of all string incarnations as the multiple uses of the harmonic oscillator solutions, which are really the first symmetric function in a series expansion of any potential.

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user anna v
@anna: The Regge theory is enjoying a remarkable comeback. It was unfairly maligned. People are now discovering that S-matrix theory is the best approach to perturbative supergravity, and the mysterious structure of QCD Regge poles is again active in AdS/QCD. Regge theory wasn't a fad.

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Ron Maimon

3 Answers

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in the late 1960s, the strongly interacting particles were a jungle. Protons, neutrons, pions, kaons, lambda hyperons, other hyperons, additional resonances, and so on. It seemed like dozens of elementary particles that strongly interacted. There was no order. People thought that quantum field theory had to die.

However, they noticed regularities such as Regge trajectories. The minimal mass of a particle of spin $J$ went like $$ M^2 = aJ + b $$ i.e. the squared mass is a linear function of the spin. This relationship was confirmed phenomenologically for a couple of the particles. In the $M^2$-$J$ plane, you had these straight lines, the Regge trajectories.

Building on this and related insights, Veneziano "guessed" a nice formula for the scattering amplitudes of the $\pi+\pi \to \pi+\rho$ process, or something like that. It had four mesons and one of them was different. His first amplitude was the Euler beta function $$ M = \frac{\Gamma(u)\Gamma(v)}{\Gamma(u+v)}$$ where $\Gamma$ is the generalized factorial and $u,v$ are linear functions of the Mandelstam variables $s,t$ with fixed coefficients again. This amplitude agrees with the Regge trajectories because $\Gamma(x)$ has poles for all non-positive integers. These poles in the amplitude correspond to the exchange of particles in the $s,t$ channels. One may show that if we expand the amplitude to the residues, the exchanged particles' maximum spin is indeed a linear function of the squared mass, just like in the Regge trajectory.

So why are there infinitely many particles that may be exchanged? Susskind, Nielsen, Yoneya, and maybe others realized that there has to be "one particle" of a sort that may have any internal excitations - like the Hydrogen atom. Except that the simple spacing of the levels looked much easier than the Hydrogen atom - it was like harmonic oscillators. Infinitely many of them were still needed. They ultimately realized that if we postulate that the mesons are (open) strings, you reproduce the whole Veneziano formula because of an integral that may be used to define it.

One of the immediate properties that the "string concept" demystified was the "duality" in the language of the 1960s - currently called the "world sheet duality". The amplitude $M$ above us $u,v$-symmetric. But it can be expanded in terms of poles for various values of $u$; or various values of $v$. So it may be calculated as a sum of exchanges purely in the $s$-channel; or purely in the $t$-channel. You don't need to sum up diagrams with the $s$-channel or with the $t$-channel: one of them is enough!

This simple principle, one that Veneziano actually correctly guessed to be a guiding principle for his search of the meson amplitude, is easily explained by string theory. The diagram in which 2 open strings merge into 1 open string and then split may be interpreted as a thickened $s$-channel graph; or a thick $t$-channel graph. There's no qualitative difference between them, so they correspond to a single stringy integral for the amplitude. This is more general - one stringy diagram usually reduces to the sum of many field-theoretical Feynman diagrams in various limits. String theory automatically resums them.

Around 1970, many things worked for the strong interactions in the stringy language. Others didn't. String theory turned out to be too good - in particular, it was "too soft" at high energies (the amplitudes decrease exponentially with energies). QCD and quarks emerged. Around mid 1970s, 't Hooft wrote his famous paper on large $N$ gauge theory - in which some strings emerge, too. Only in 1997, these hints were made explicit by Maldacena who showed that string theory was the right description of a gauge theory (or many of them) at the QCD scale, after all: the relevant target space must however be higher-dimensional and be an anti de Sitter space. In AdS/CFT, much of the original strategies - e.g. the assumption that mesons are open strings of a sort - get revived and become quantitatively accurate. It just works.

Of course, meanwhile, around mid 1970s, it was also realized that string theory was primarily a quantum theory of gravity because the spin 2 massless modes inevitably exist and inevitably interact via general relativity at long distances. In the early and mid 1980s, it was realized that string theory included the right excitations and interactions to describe all particle species and all forces we know in Nature and nothing could have been undone about this insight later.

Today, we know that the original motivation of string theory wasn't really wrong: it was just trying to use non-minimal compactifications of string theory. Simpler vacua of string theory explain gravity in a quantum language long before they explain the strong interactions.

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Luboš Motl
answered Aug 19, 2011 by Luboš Motl (10,278 points) [ no revision ]
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By the way, your "counting of the intersection dimension" in string theory is crap, too. There is absolutely no reason why such ad hoc concepts should be well-defined in a physical theory and they're not. Much more generally, the concept of "total spacetime dimension" is extremely subtle - the number of "Planckian" or "stringy" sized dimensions is always ambiguous and different dual descriptions generally yield different answers: ST isn't a fully local QFT, after all. Only large dimensions - much larger than the string/Planck scale - can be "unambiguously" counted.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Luboš Motl
@Lubos: I agree with you about the properties of standard string theory completely, uniqueness yada yada. What I am trying to make you understand is that there are hidden bootstrap assumptions used in constructing the standard theory. I agree with you about dimension counting for strong coupling, it is totally wrong, but that's because of the bootstrap nature of the string. Naive dimension counting for getting intersections in nearly flat space works for crap-strings (rubber bands). The fractal dimension of the embedding might be nonsense for real strings, but that's not the point.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Ron Maimon
Dear @Ron, it's very interesting. But could you please be a little bit specific what the "hidden [bootstrap] assumptions" are? It's hard to imagine anything real behind your words at this point. I was just innocently stating that the particular deformation of string interactions you proposed was inconsistent. As far as I can say, one can prove it without any assumptions that would have to remain "hidden". You: "The fractal dimension of the embedding might be nonsense for real strings, but that's not the point." - OK, but what is your point then? Fractal dimension depends on UV physics.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Luboš Motl
@Lubos: I wasn't proposing a "deformation" of strings, I was telling you that you are using bootstrap assumption that the string exchanges other strings and nothing else. This is not demanded by any consistency condition (except for being a correct holographic gravity theory), and there are models of stringlike objects in which it fails.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Ron Maimon
@Lubos: here is a model physics.stackexchange.com/questions/13828/chentile-strings.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Ron Maimon
Most recent comments show all comments
@Lubos: as for the other stuff, I can construct an example field theory with low energy "strings" but high energy crap for you, but I do not want to fill up the comments. I will do so as an answer or a question. I know this is possible because I tried to find string theory by following the propaganda, but it is impossible to derive the interactions without knowing that the only way strings interact is by exchanging strings, and not something else.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Ron Maimon
Dear @Ron, Brandenberger-Vafa or string gas cosmology etc. isn't a paper about the existence and character of fundamental interactions in string theory; it is a paper about the "derived" impact of geometrical arrangement of strings on cosmology. Whether the strings are intersecting or not is irrelevant and the rules for the interactions of strings are independent of the spacetime dimension and they work in such a way that you may neglect the possibility of self-intersection as a measure-zero problem: the world sheet is always smooth around the interaction "point", even in $d=2$.

This post imported from StackExchange Physics at 2014-03-17 04:02 (UCT), posted by SE-user Luboš Motl
+ 4 like - 0 dislike

I liked this video, where Susskind explains how he and some friends discovered string theory in the context of meson scattering.

(This is just a very preliminary answer, the video is probably way below your level ... :-P, I will take it back as soon as it is superseded)

answered Aug 18, 2011 by Dilaton (6,240 points) [ revision history ]
You`re welcome :-))). He starts drawing a plot of the Regge Trajectories and in the course of the lecture nicely derives it from meson scattering, including the transformation to light cone coordinates step by step. I dont remember all of the details, will have to rewatch it when I busy myself more seriously with the whole string course of Lenny Susskind ...

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Dilaton
+ 3 like - 0 dislike

Well I believe the original clue was Regge trajectories. It was observed that if you plotted mass squared vs. angular momentum for strongly interacting resonances, they tended to follow straight lines. This could be explained as the spectrum of rotating strings connecting massless particles.

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user user1631
answered Aug 18, 2011 by user1631 (60 points) [ no revision ]
This is what I've heard as well.

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user David Z
Interesting. What I heard about the origins was actually something to do with Veneziano and beta function. How does this relate?

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Marek
Okay, I think I can answer my own question. Since the spectrum lies on the Regge trajectories it means it can be interpreted as the poles of the beta function. I'd still want to have more details though (ideally a reference).

This post imported from StackExchange Physics at 2014-03-17 04:01 (UCT), posted by SE-user Marek

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