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Density matrices in quantum gravity

Tarek Anous, Jorrit Kruthoff, Raghu Mahajan

2020SciPost Physics36 citationsDOIOpen Access PDF

Abstract

We study density matrices in quantum gravity, focusing on topology change. We argue that the inclusion of bra-ket wormholes in the gravity path integral is not a free choice, but is dictated by the specification of a global state in the multi-universe Hilbert space. Specifically, the Hartle-Hawking (HH) state does not contain bra-ket wormholes. It has recently been pointed out that bra-ket wormholes are needed to avoid potential bags-of-gold and strong subadditivity paradoxes, suggesting a problem with the HH state. Nevertheless, in regimes with a single large connected universe, approximate bra-ket wormholes can emerge by tracing over the unobserved universes. More drastic possibilities are that the HH state is non-perturbatively gauge equivalent to a state with bra-ket wormholes, or that the third-quantized Hilbert space is one-dimensional. Along the way we draw some helpful lessons from the well-known relation between worldline gravity and Klein-Gordon theory. In particular, the commutativity of boundary-creating operators, which is necessary for constructing the alpha states and having a dual ensemble interpretation, is subtle. For instance, in the worldline gravity example, the Klein-Gordon field operators do not commute at timelike separation.

Topics & Concepts

WormholeHilbert spaceQuantum gravityPhysicsPath integral formulationGauge (firearms)QuantumTheoretical physicsQuantum stateState (computer science)Semiclassical gravitySpin foamSubadditivityQuantum field theoryTopology (electrical circuits)Field (mathematics)SpacetimeState spaceCommutative propertyEuclidean quantum gravityMathematical physicsGauge theorySpace (punctuation)Extension (predicate logic)MathematicsQuantum mechanicsClassical mechanicsDual (grammatical number)Ground stateNoncommutative and Quantum Gravity TheoriesBlack Holes and Theoretical PhysicsCosmology and Gravitation Theories
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