Algebras and States in JT Gravity

We analyze the algebra of boundary observables in canonically quantised JT gravity with or without matter. In the absence of matter, this algebra is commutative, generated by the ADM Hamiltonian. After coupling to a bulk quantum field theory, it becomes a highly noncommutative algebra of Type II$_\infty$ with a trivial center. As a result, density matrices and entropies on the boundary algebra are uniquely defined up to, respectively, a rescaling or shift. We show that this algebraic definition of entropy agrees with the usual replica trick definition computed using Euclidean path integrals. Unlike in previous arguments that focused on $\mathcal{O}(1)$ fluctuations to a black hole of specified mass, this Type II$_\infty$ algebra describes states at all temperatures or energies. We also consider the role of spacetime wormholes. One can try to define operators associated with wormholes that commute with the boundary algebra, but this fails in an instructive way. In a regulated version of the theory, wormholes and topology change can be incorporated perturbatively. The bulk Hilbert space $\mathcal{H}_\mathrm{bulk}$ that includes baby universe states is then much bigger than the space of states $\mathcal{H}_\mathrm{bdry}$ accessible to a boundary observer. However, to a boundary observer, every pure or mixed state on $\mathcal{H}_\mathrm{bulk}$ is equivalent to some pure state in $\mathcal{H}_\mathrm{bdry}$.

[1]  David K. Kolchmeyer von Neumann algebras in JT gravity , 2023, Journal of High Energy Physics.

[2]  T. Mertens,et al.  Solvable models of quantum black holes: a review on Jackiw–Teitelboim gravity , 2022, Living Reviews in Relativity.

[3]  V. Chandrasekaran,et al.  Large N algebras and generalized entropy , 2022, Journal of High Energy Physics.

[4]  Henry W. Lin The bulk Hilbert space of double scaled SYK , 2022, Journal of High Energy Physics.

[5]  D. Stanford,et al.  Firewalls from wormholes , 2022, 2208.01625.

[6]  Geoffrey Penington,et al.  The black hole interior from non-isometric codes and complexity , 2022, 2207.06536.

[7]  Henry W. Lin,et al.  Looking at supersymmetric black holes for a very long time , 2022, SciPost Physics.

[8]  V. Chandrasekaran,et al.  An algebra of observables for de Sitter space , 2022, Journal of High Energy Physics.

[9]  E. Witten Gravity and the crossed product , 2021, Journal of High Energy Physics.

[10]  Hong Liu,et al.  Emergent times in holographic duality , 2021, 2112.12156.

[11]  Hong Liu,et al.  Causal connectability between quantum systems and the black hole interior in holographic duality , 2021, 2110.05497.

[12]  V. Jones Von Neumann Algebras , 2020, Lectures on von Neumann Algebras.

[13]  Clifford V. Johnson Explorations of nonperturbative Jackiw-Teitelboim gravity and supergravity , 2020, 2006.10959.

[14]  Clifford V. Johnson Nonperturbative Jackiw-Teitelboim gravity , 2020 .

[15]  D. Marolf,et al.  Transcending the ensemble: baby universes, spacetime wormholes, and the order and disorder of black hole information , 2020, Journal of High Energy Physics.

[16]  Phil Saad Late Time Correlation Functions, Baby Universes, and ETH in JT Gravity , 2019, 1910.10311.

[17]  E. Witten,et al.  JT gravity and the ensembles of random matrix theory , 2019, Advances in Theoretical and Mathematical Physics.

[18]  Ahmed Almheiri,et al.  The entropy of bulk quantum fields and the entanglement wedge of an evaporating black hole , 2019, Journal of High Energy Physics.

[19]  Henry W. Lin,et al.  Symmetries near the horizon , 2019, Journal of High Energy Physics.

[20]  M. Berkooz,et al.  Towards a full solution of the large N double-scaled SYK model , 2018, Journal of High Energy Physics.

[21]  Zhenbin Yang The quantum gravity dynamics of near extremal black holes , 2018, Journal of High Energy Physics.

[22]  A. Kitaev,et al.  Statistical mechanics of a two-dimensional black hole , 2018, Journal of High Energy Physics.

[23]  Jennifer Lin Entanglement entropy in Jackiw-Teitelboim Gravity , 2018, 1807.06575.

[24]  D. Harlow,et al.  The factorization problem in Jackiw-Teitelboim gravity , 2018, Journal of High Energy Physics.

[25]  Xiao-Liang Qi,et al.  Eternal traversable wormhole , 2018, 1804.00491.

[26]  Gabor Sarosi,et al.  AdS$_{2}$ holography and the SYK model , 2017, 1711.08482.

[27]  J. Maldacena,et al.  Conformal symmetry and its breaking in two dimensional Nearly Anti-de-Sitter space , 2016, 1606.01857.

[28]  J. Polchinski,et al.  Models of AdS2 backreaction and holography , 2014, 1402.6334.

[29]  Aitor Lewkowycz,et al.  Quantum corrections to holographic entanglement entropy , 2013, 1307.2892.

[30]  Aitor Lewkowycz,et al.  Generalized gravitational entropy , 2013, 1304.4926.

[31]  I. Morrison,et al.  Group averaging for de Sitter free fields , 2008, 0810.5163.

[32]  O. Shvedov On Correspondence of BRST-BFV, Dirac, and Refined Algebraic Quantizations of Constrained Systems , 2001, hep-th/0111270.

[33]  D. Marolf Group Averaging and Refined Algebraic Quantization: Where are we now? , 2000, gr-qc/0011112.

[34]  Y. Verbin,et al.  Lower-dimensional gravity. , 1994, Physical review. D, Particles and fields.

[35]  Marc Henneaux,et al.  Lectures on the antifield-BRST formalism for gauge theories , 1990 .

[36]  S. Giddings,et al.  Baby Universes, Third Quantization and the Cosmological Constant , 1989 .

[37]  S. Coleman Black holes as red herrings: topological fluctuations and the loss of quantum coherence , 1988 .

[38]  C. Teitelboim Gravitation and hamiltonian structure in two spacetime dimensions , 1983 .

[39]  S. Hawking,et al.  Action Integrals and Partition Functions in Quantum Gravity , 1977 .

[40]  E. Wichmann,et al.  ON THE DUALITY CONDITION FOR QUANTUM FIELDS , 1976 .