Non-metricity Approach to Jackiw-Teitelboim Gravity: Constructing a Two-Dimensional Gravity Model

This new formulation of JT gravity in terms of non-metricity offers a fresh perspective on the AdS/CFT correspondence in two dimensions, although much remains to be explored. Here's how: New Holographic Dictionary: Traditional AdS/CFT relies on relating geometric quantities in the bulk (like the metric) to field theory quantities on the boundary. Since this new formulation is based on non-metricity, it suggests a need to develop a new holographic dictionary. This dictionary would relate quantities like the non-metricity tensor and its derived scalar, AQ, to corresponding operators in the dual quantum theory. Exploring Non-Riemannian Holography: Most holographic studies focus on gravity theories with standard Riemannian geometry. This work, however, delves into the relatively unexplored territory of non-Riemannian holography. Understanding the holographic dual of a theory like symmetric teleparallel gravity, where both curvature and torsion vanish, could provide novel insights into the nature of quantum gravity and the emergence of spacetime geometry from more fundamental degrees of freedom. Simplified Model for Holographic Studies: JT gravity is already known for its simplicity and solvability, making it a useful toy model for studying AdS/CFT. This new formulation, by potentially simplifying certain aspects of the theory, could further facilitate holographic computations and provide a testing ground for new ideas in holography. However, the paper acknowledges that holography in the context of symmetric teleparallel gravity is not well understood. Further research is needed to fully grasp the implications of this new formulation for the AdS2/CFT1 correspondence.

Yes, the potential presence of ghosts, even if confined to sectors beyond the conformal mode, poses significant theoretical challenges and potential instabilities for this model: Violation of Unitarity: Ghosts typically lead to negative norm states in the quantum theory, jeopardizing the probabilistic interpretation of quantum mechanics and violating unitarity. A unitary theory is essential for consistent time evolution and a well-defined notion of probability in quantum mechanics. Runaway Instabilities: Ghosts can introduce instabilities in the theory. Since they have kinetic energy unbounded from below, the system can transition to states of arbitrarily negative energy by creating an unlimited number of ghost particles. This runaway behavior signals a breakdown of the theory's stability. Challenges for Quantization: The presence of ghosts complicates the process of consistently quantizing the theory. Standard quantization procedures often rely on a well-defined Hamiltonian that is bounded from below, a condition violated by ghost fields. While the paper identifies a condition (a < 0) for the conformal mode to be non-ghostlike, it acknowledges the need for a more thorough Hamiltonian analysis to definitively rule out ghosts in other sectors. The presence of such ghosts would necessitate modifications or extensions to the theory to address these fundamental issues.

This work offers intriguing implications for understanding the relationship between different geometric formulations of gravity, especially as we seek a consistent theory of quantum gravity: Beyond Riemannian Geometry: It highlights the potential importance of exploring non-Riemannian geometries in the quest for quantum gravity. While Einstein's general relativity relies on Riemannian geometry, characterized by the metric tensor, this work demonstrates that alternative geometric frameworks, like symmetric teleparallel gravity based on non-metricity, can also describe gravity, at least in specific cases like JT gravity. Equivalence at the Classical Level: The construction of a symmetric teleparallel equivalent of JT gravity reinforces the idea that different geometric formulations of gravity, while mathematically distinct, might be physically equivalent at the classical level. This echoes the well-known result that teleparallel gravity, based on torsion, can be made equivalent to general relativity. Quantum Discrepancies: However, the potential for ghosts in this non-metricity formulation of JT gravity hints at the possibility that these different geometric formulations might not be equivalent at the quantum level. Quantum effects could amplify subtle differences between these frameworks, leading to distinct quantum theories of gravity. This work underscores the importance of investigating diverse geometric approaches to gravity, as they might hold the key to unlocking a deeper understanding of quantum gravity. It suggests that the path to quantum gravity might involve going beyond the familiar terrain of Riemannian geometry and exploring the rich landscape of alternative geometric frameworks.