Background field and time dependence effects in holographic models

TL;DR

This thesis explores background field and time dependence effects in holographic models, including applications to QCD vacuum instabilities, chiral transition temperature splitting, and condensed matter systems, using top-down and bottom-up approaches.

Contribution

It provides new holographic predictions for magnetic field-induced QCD vacuum instability and develops a numerical method for time-dependent spectral functions in condensed matter models.

Findings

Holographic description of rho meson condensation under magnetic fields

Partial restoration of chiral symmetry at finite temperature

Development of pseudospectral numerical method for time-dependent spectral functions

Abstract

This thesis deals with applications of holographic dualities to the study of background field and time dependence effects in strongly coupled field theories. The first chapters (2-5) aim to provide a self-contained review of the Sakai-Sugimoto model (SSM) as a top-down approach to holographic QCD, introducing first the necessary background on QCD, string theory and AdS/CFT. Chapter 7 reviews finite temperature holography, to be used in the subsequent chapters. We use the non-Abelian ($N_f = 2$) SSM to study a possible magnetically induced instability of the QCD vacuum towards a superconducting phase, as previously discussed in phenomenological QCD models and there referred to as "rho meson condensation". We find that this instability can indeed be holographically described by the SSM, and obtain increasingly higher predictions for the necessary critical magnetic field in increasingly complicated (i.e. less simplified) set-ups. The obtained results are presented in chapter 6 and are based on arXiv:1105.2217 and arXiv:1309.5042. In chapter 8 we discuss the splitting of chiral transition temperatures per flavour in the finite temperature regime of the $N_f = 2$ SSM, indicating an intermediate phase where chiral symmetry is only partially restored. This was previously presented in arXiv:1303.5674. In chapter 9, instead of a top-down approach, bottom-up models known as "AdS-Vaidya" models are used in the context of condensed matter applications to study far-from-equilibrium behaviour of strongly coupled electron systems. A notion of a time-dependent spectral function is defined and calculated in Reissner-Nordstr\"om-AdS$_4$-Vaidya as a very first step towards extracting in principle measurable quantities in time-resolved ARPES experiments [arXiv:1407.5975]. Focus is put on explaining the used numerical method (pseudospectral method).