Real-time gauge/gravity duality: Prescription, Renormalization and Examples (0812.2909v2)

Abstract: We present a comprehensive analysis of the prescription we recently put forward for the computation of real-time correlation functions using gauge/gravity duality. The prescription is valid for any holographic supergravity background and it naturally maps initial and final data in the bulk to initial and final states or density matrices in the field theory. We show in detail how the technique of holographic renormalization can be applied in this setting and we provide numerous illustrative examples, including the computation of time-ordered, Wightman and retarded 2-point functions in Poincare and global coordinates, thermal correlators and higher-point functions.

• The paper introduces a real-time holographic prescription that translates bulk initial and final data into boundary states.
• The paper extends holographic renormalization to Lorentzian setups by using boundary counterterms to cancel divergences.
• The paper establishes matching conditions ensuring causal correlators, validated through examples including rotating black holes.

Real-time Gauge/Gravity Duality: Prescription, Renormalization and Examples

The research paper by Kostas Skenderis and Balt C. van Rees explores the computation of real-time correlation functions using gauge/gravity duality, extending the existing AdS/CFT correspondence to a regime where real-time dynamics and non-trivial initial and final states can be rigorously analyzed. This work provides a comprehensive framework that encompasses prescription, renormalization, and diverse examples to validate the approach.

The paper introduces a methodological prescription applicable across any holographic supergravity background, translating initial and final data in the holographic bulk to boundary states or density matrices in the field theory. Critically, this prescription relies solely on boundary conditions and regularity in the bulk's interior, which are crucial for computations within the supergravity approximation where classical dynamics dominate.

Holographic Renormalization in Real-Time

The researchers adapt holographic renormalization, a crucial step in managing divergences arising from the non-compactness of bulk spacetime, to the real-time context. Despite additional complexities owing to Lorentzian signatures and the temporal non-compactness in real-time setups, they demonstrate that these divergences can be effectively countered through boundary counterterms. The analysis guarantees that the same counterterms used in Euclidean setups are sufficient to yield finite results even for Lorentzian spacetimes.

Significant Results and Matching Conditions

The paper exhibits how the production of correct causal structures and $i\epsilon$ insertions in boundary correlators emerge naturally from the bulk computations, reflecting an essential compatibility between causality and holography. This feature is critical in resolving known ambiguities in such dualities, particularly in the presence of bulk and boundary lightcone discrepancies.

For practical computations, the authors establish matching conditions governing the behavior across different segments of the holographic spacetime, ensuring continuity and appropriate propagation of initial and final data through the holographic setup. These matching conditions are derived from a thorough examination of the variational principles required for a well-posed holographic problem, incorporating corner terms when necessary.

Application to Real-Time Scenarios

Illustrative examples underscore the versatility of the described methodology. These include standard AdS/CFT setups as well as more complex scenarios such as rotating black holes, which require implementing complex metrics to accommodate the non-trivial real-time features, such as chemical potential effects. For instance, navigating the peculiarities of rotating BTZ black holes involves crafting suitable CFT contours that reflect the dual thermodynamic ensembles, incorporating angular momentum in thermal states. Such examples demonstrate the framework’s ability to encompass various state configurations, extending beyond equilibrium states into non-equilibrium dynamics.

Future Directions and Practical Implications

The development of a real-time holographic prescription has far-reaching implications for theoretical and practical research in quantum field theories and gravitational systems. By facilitating the paper of non-equilibrium phenomena through duality, it opens avenues for exploring real-time dynamics in a variety of contexts, including the modeling of the quark-gluon plasma and other systems where traditional Euclidean methods fall short.

Furthermore, this research provides the foundational tools to extend such dualities to more intricate setups, such as time-dependent or dynamically evolving systems. Thus, the versatility of this approach, combined with its rigorous treatment of renormalization, holds promise for addressing open questions in holography, particularly those involving causality and the nature of spacetime singularities.

In conclusion, Skenderis and van Rees have enriched the gauge/gravity duality framework by providing a robust methodology for real-time analysis within holographic theories, expanding both the theoretical depth and practical applicability of holographic principles in the paper of quantum dynamics and beyond.