Litcius/Paper detail

On exact-WKB analysis, resurgent structure, and quantization conditions

Naohisa Sueishi, Syo Kamata, Tatsuhiro Misumi, Mithat Ünsal

2020Journal of High Energy Physics34 citationsDOIOpen Access PDF

Abstract

A bstract There are two well-known approaches to studying nonperturbative aspects of quantum mechanical systems: saddle point analysis of the partition functions in Euclidean path integral formulation and the exact-WKB analysis based on the wave functions in the Schrödinger equation. In this work, based on the quantization conditions obtained from the exact-WKB method, we determine the relations between the two formalism and in particular show how the two Stokes phenomena are connected to each other: the Stokes phenomenon leading to the ambiguous contribution of different sectors of the path integral formulation corresponds to the change of the “topology” of the Stoke curves in the exact-WKB analysis. We also clarify the equivalence of different quantization conditions including Bohr-Sommerfeld, path integral and Gutzwiller’s ones. In particular, by reorganizing the exact quantization condition, we improve Gutzwiller’s analysis in a crucial way by bion contributions (incorporating complex periodic paths) and turn it into an exact result. Furthermore, we argue the novel meaning of quasi-moduli integral and provide a relation between the Maslov index and the intersection number of Lefschetz thimbles.

Topics & Concepts

Path integral formulationPhysicsQuantization (signal processing)Euclidean geometrySaddle pointGeometric quantizationFormalism (music)PropagatorCanonical quantizationQuantumMathematical physicsSaddleTheoretical physicsEquivalence relationClassical mechanicsMethods of contour integrationQuantum mechanicsEquivalence (formal languages)Stochastic quantizationMathematical analysisIntegral equationQuantum field theoryHamiltonian (control theory)RenormalizationStatistical physicsQuantum Mechanics and Non-Hermitian PhysicsMathematical functions and polynomialsQuantum chaos and dynamical systems