Litcius/Paper detail

On Gauss-Bonnet gravity and boundary conditions in Lorentzian path-integral quantization

Gaurav Narain

2021Journal of High Energy Physics18 citationsDOIOpen Access PDF

Abstract

A bstract Recently there has been a surge of interest in studying Lorentzian quant urn cosmology using Picard-Lefschetz methods. The present paper aims to explore the Lorentzian path-integral of Gauss-Bonnet gravity in four spacetime dimensions with metric as the field variable. We employ mini-superspace approximation and study the variational problem exploring different boundary conditions. It is seen that for mixed boundary conditions non-trivial effects arise from Gauss-Bonnet sector of gravity leading to additional saddle points for lapse in some case. As an application of this we consider the No-boundary proposal of the Universe with two different settings of boundary conditions) and compute the transition amplitude using Picard-Lefschetz formalism. In first case the transition amplitude is a superposition of a Lorentzian and a Euclidean geometrical configuration leading to interference incorporating non-perturbative effects coming from Gauss-Bonnet sector of gravity. In the second case involving complex initial momentum we note that the transition amplitude is an analogue of Hartle-Hawking wave-function with non-perturbative correction coming from Gauss-Bonnet sector of gravity.

Topics & Concepts

PhysicsSuperposition principleBoundary value problemAmplitudeClassical mechanicsBoundary (topology)Quantization (signal processing)CurvatureQuantum cosmologyQuantum gravityTheoretical physicsSaddle pointMathematical physicsLinearized gravityEuclidean geometrySpacetimeGravitationMetric (unit)Causal structureSemiclassical gravityEuclidean quantum gravityCosmologyGravitational fieldInstantonField (mathematics)f(R) gravityBoundary conformal field theoryMomentum (technical analysis)Hamiltonian constraintSaddleHeat kernelUniverseNoncommutative and Quantum Gravity TheoriesCosmology and Gravitation TheoriesBlack Holes and Theoretical Physics