Path integral suppression of badly behaved causal sets
Peter Carlip, Steven Carlip, Sumati Surya
Abstract
Abstract Causal set theory is a discrete model of spacetime that retains a notion of causal structure. We understand how to construct causal sets that approximate a given spacetime, but most causal sets are not at all manifold-like, and must be dynamically excluded if something like our Universe is to emerge from the theory. Here we show that the most common of these ‘bad’ causal sets, the Kleitman–Rothschild orders, are strongly suppressed in the gravitational path integral, and we provide evidence that a large class of other ‘bad’ causal sets are similarly suppressed. It thus becomes plausible that continuum behavior could emerge naturally from causal set quantum theory.
Topics & Concepts
Causal setsPhysicsCausal structureSpacetimeClass (philosophy)Quantum gravityManifold (fluid mechanics)Path integral formulationSet (abstract data type)Theoretical physicsCausality (physics)Construct (python library)Pure mathematicsQuantumQuantum mechanicsMathematicsQuantum field theory in curved spacetimeComputer scienceArtificial intelligenceEngineeringProgramming languageMechanical engineeringNoncommutative and Quantum Gravity TheoriesCosmology and Gravitation TheoriesBlack Holes and Theoretical Physics