Large mass expansion of the one-loop effective action induced by a scalar field on the two-dimensional Minkowski background with non-trivial $(1+1)$ splitting

TL;DR

This paper derives a large mass expansion for the one-loop effective action of a scalar field in two-dimensional Minkowski space with a non-trivial coordinate system, revealing both analytic and non-analytic terms in the mass parameter.

Contribution

It provides a new large mass expansion including non-analytic terms and a general expression for one-loop corrections on non-stationary backgrounds.

Findings

Expansion includes both analytic and non-analytic terms in inverse mass squared.

Derived a general, unambiguous formula for one-loop effective action corrections.

Applicable to non-stationary spacetime backgrounds.

Abstract

A large mass expansion of the one-loop effective action of a scalar field on the two-dimensional Minkowski spacetime is found in the system of coordinates, where the metric $g_{\mu\nu}(t,x)\neq\eta_{\mu\nu}=diag(1,-1)$, and $g_{\mu\nu}(t,x)$ tends to $\eta_{\mu\nu}$ at the spatial and temporal infinities. It is shown that, apart from the Coleman-Weinberg potential, this expansion contains the terms both analytic and non-analytic in $m^{-2}$, where $m$ is the mass of a scalar field. A general unambiguous expression for the one-loop correction to the effective action on non-stationary backgrounds is derived.