The Hydrodynamic Approach to Quantum Gravity
T. Banks
TL;DR
This paper proposes a hydrodynamic framework for quantum gravity, linking Einstein's equations to quantum systems via density matrices assigned to causal diamonds, and explores how quantum field theory emerges from this approach.
Contribution
It introduces a novel hydrodynamic interpretation of Einstein's equations as quantum system equations using density matrices on causal diamonds.
Findings
Defines the empty diamond state as a quantum vacuum analog
Describes a unitary embedding of Hilbert spaces along geodesics
Discusses compatibility with quantum field theory
Abstract
Several papers from the mid to late 1990s suggest that Einstein's equations should be thought of as the hydrodynamic equations of a special class of quantum systems. A classical solution defines subsystems by dividing space-time up into CAUSAL DIAMONDS and Einstein's equations are the hydrodynamics of a system that assigns a density matrix to each diamond whose modular Hamiltonian K has expectation value and fluctuation both given by A/4G. A is the maximal d-2 volume on the boundary of the diamond and G is Newton's constant. These properties define the EMPTY DIAMOND STATE, the analog of the quantum field theory (QFT) vacuum, in the background geometry. The assignment of density matrices to each diamond enables one to define the analog of half sided modular flow along geodesics in the background manifold, as a unitary embedding of the Hilbert space of a given diamond into the next one in…
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Taxonomy
TopicsQuantum Mechanics and Applications · Cosmology and Gravitation Theories · Quantum Electrodynamics and Casimir Effect