Litcius/Paper detail

Integrating out heavy fields in the path integral using the background-field method: general formalism

Stefan Dittmaier, Sebastian Schuhmacher, Maximilian Stahlhofen

2021The European Physical Journal C45 citationsDOIOpen Access PDF

Abstract

Abstract Building on an older method used to derive non-decoupling effects of a heavy Higgs boson in the Standard Model, we describe a general procedure to integrate out heavy fields in the path integral. The derivation of the corresponding effective Lagrangian including the one-loop contributions of the heavy particle(s) is particularly transparent, flexible, and algorithmic. The background-field formalism allows for a clear separation of tree-level and one-loop effects involving the heavy fields. Using expansion by regions the one-loop effects are further split into contributions from large and small momentum modes. The former are contained in Wilson coefficients of effective operators, the latter are reproduced by one-loop diagrams involving effective tree-level couplings. The method is illustrated by calculating potential non-decoupling effects of a heavy Higgs boson in a singlet Higgs extension of the Standard Model. In particular, we work in a field basis corresponding to mass eigenstates and properly take into account non-vanishing mixing between the two Higgs fields of the model. We also show that a proper choice of renormalization scheme for the non-standard sector of the underlying full theory is crucial for the construction of a consistent effective field theory.

Topics & Concepts

Higgs bosonRenormalizationPhysicsFormalism (music)Path integral formulationBosonParticle physicsHiggs sectorEigenvalues and eigenvectorsEffective field theoryElectroweak interactionPhysics beyond the Standard ModelElementary particleHiggs fieldStandard Model (mathematical formulation)LagrangianFeynman diagramBasis (linear algebra)Tachyonic fieldTheoretical physicsQuantum field theoryStatistical physicsPath (computing)Field (mathematics)Extension (predicate logic)Particle physics theoretical and experimental studiesQuantum Chromodynamics and Particle InteractionsHigh-Energy Particle Collisions Research