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Liouville and JT Quantum Gravity - Holography and Matrix Models

Offered By: Institute for Advanced Study via YouTube

Tags

Quantum Gravity Courses Group Theory Courses Theoretical Physics Courses Holography Courses Quantum Groups Courses JT Gravity Courses

Course Description

Overview

Explore the intricacies of Liouville and JT Quantum Gravity in this 55-minute conference talk by Thomas Mertens from Ghent University, presented at the Online Workshop on Qubits and Black Holes. Delve into holography and matrix models, examining fixed-length boundaries, disk partition functions, and multi-boundary amplitudes. Investigate the JT limit, density of states, and Euclidean wormholes. Uncover the group theory interpretation of JT gravity and the quantum group interpretation of Liouville supergravity. Analyze the boundary two-point function and explore Liouville gravity as a dilaton gravity. Gain insights into black hole solutions and the first law, providing evidence for the quantum group interpretation of Liouville gravity.

Syllabus

Intro
Outline
Introduction
Liouville gravity: Fixed-length boundaries
Strategy
Disk partition function: JT limit
Disk partition function: density of states
Multi-boundary amplitudes: Euclidean wormhole
Multi-boundary amplitudes: genus zero
Boundary two-point function (1)
Group theory interpretation of JT gravity
Quantum group interpretation of Liouville supergravity
Liouville gravity as a dilaton gravity
Conclusion
Quantum group interpretation of Liouville gravity
Evidence l: Black hole solution and first law


Taught by

Institute for Advanced Study

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