2004
DOI: 10.1088/1126-6708/2004/07/014
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String excitation energies in SU(N) gauge theories beyond the free-string approximation

Abstract: Abstract:In the presence of a static quark-antiquark pair, the spectrum of the lowlying states in SU(N ) gauge theories is discrete and likely to be described, at large quark separations r, by an effective string theory. The expansion of the excitation energies in powers of 1/r, which derives from the latter, involves an increasing number of unknown couplings that characterize the string self-interactions. Using open-closed string duality, we show that the possible values of the couplings are constrained by a … Show more

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Cited by 199 publications
(347 citation statements)
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“…We demonstrate this by reconstructing the full Nambu-Goto action in D dimensions in static gauge starting from the action of D − 2 free massless bosons; we also apply the same method to single boson Lagrangians with generic potential. Next, we use an idea first proposed by Lüscher and Weisz [22] to reconstruct the cylinder partition function of t-deformed rational CFTs, linking the result to the exact g-function formula proposed for massless TBA flows in [23]. The effect of this deformation appears to be easily computable also for other physical observables; the last example we briefly discuss concerns one-point functions on a cylinder geometry.…”
Section: Jhep10(2016)112mentioning
confidence: 99%
See 1 more Smart Citation
“…We demonstrate this by reconstructing the full Nambu-Goto action in D dimensions in static gauge starting from the action of D − 2 free massless bosons; we also apply the same method to single boson Lagrangians with generic potential. Next, we use an idea first proposed by Lüscher and Weisz [22] to reconstruct the cylinder partition function of t-deformed rational CFTs, linking the result to the exact g-function formula proposed for massless TBA flows in [23]. The effect of this deformation appears to be easily computable also for other physical observables; the last example we briefly discuss concerns one-point functions on a cylinder geometry.…”
Section: Jhep10(2016)112mentioning
confidence: 99%
“…To support this conjecture, we will not work in the framework of the exact g-function formula extracted from [23], which would need to be generalized on a case-by-case basis. Instead, we shall adapt an alternative method originally devised by Lüscher and Weisz [22] for free massless bosons in the effective string theory context. This more general and powerful approach is implemented in section 7.2, leading to a confirmation of the Ising model result, which appears to be valid for a generic CFT.…”
Section: Jhep10(2016)112mentioning
confidence: 99%
“…This expression incorporates all the known universal corrections to the flux tube energy, when one expands E(l) in powers of 1/l 2 σ [30][31][32][33][34]. (See also [35,36].) It has also been shown to arise as a good approximation at small l from the near-integrability of the world-sheet action [37][38][39][40][41][42][43].…”
Section: String Tensionsmentioning
confidence: 99%
“…Thus the effective string action predicts the spectrum of such closed flux tubes. On the other hand Lorentz invariance constrains the p-dependence of E n (p, l) and this in turn will constrain the possible form of S eff [30,31]. More generally, the conformal invariance of the effective string action [24] can also be used to constrain its form [32,33].…”
Section: Effective String Actionmentioning
confidence: 99%
“…This corresponds to noting that if we write the effective string action in 'static gauge' and express it in a series of powers of the derivative of the transverse fluctuation field h(x), then the leading Gaussian kinetic term for h gives this universal O(1/l) contribution to E n (l). Much more recently it was found [30] that the next term in the derivative expansion of S eff [h] is universal, so that the next term in an expansion of E n (l), at O(1/l 3 ), is also universal. This was also shown [32,33], at much the same time, and with a stronger result in D = 3 + 1, using the Polchinski-Strominger conformal gauge approach [24].…”
Section: Effective String Actionmentioning
confidence: 99%