Non-perturbative aspects of gauge theories from gauge-gravity dualities

Abstract

We consider two established supergravities which are known to provide the low-energy effective description of either superstring theory or M-theory: the six-dimensional theory of Romans, and the maximal supergravity in seven dimensions. We compactify on an S1 and T2, respectively, to obtain 5D sigma-models coupled to gravity, and spectra of bosonic excitations are computed numerically by fluctuating fields on backgrounds which holographically realise confinement. We propose a method to detect mixing effects between scalar resonances and the pseudo-Nambu--Goldstone boson associated with spontaneous breaking of conformal invariance: the dilaton. This test consists of neglecting a key component of the spin-0 fluctuation variables, effectively disregarding their back-reaction on the underlying geometry; where discrepancies arise compared to the proper calculation we infer dilaton mixing. In both cases this analysis evinces a parametrically light dilaton. For each theory we also uncover a tachyonic instability within their parameter space. We hence proceed to investigate their respective phase structures, reasoning that some mechanism must render the instabilities physically inaccessible. We compile a catalogue of geometrically distinct backgrounds within each theory, and derive general expressions for their holographically renormalised free energy F. Another numerical routine is used to systematically extract data for some special deformation parameters, and F is plotted in units of an appropriate universal scale. Our analysis proves fruitful: each theory shows evidence of a first-order phase transition which induces the spontaneous decompactification of the shrinking dimension before the instability manifests, favouring instead a branch of singular solutions. The light dilaton resonance appears only along a metastable portion of the branch of confining backgrounds.