Stress Tensors for Instantaneous Vacua in 1+1 Dimensions

TL;DR

This paper explicitly calculates the regularized stress-energy tensor for massless fields in 1+1 dimensions on arbitrary Cauchy surfaces, revealing how geometry and topology influence quantum vacuum states.

Contribution

It provides a new explicit formula for the stress-energy tensor in 1+1 dimensions for various boundary conditions and geometries, using only conservation laws and the trace anomaly.

Findings

Derived explicit stress tensor expressions for different field types and boundary conditions.

Connected stress tensor invariants to quantum state properties in curved spacetime.

Applied results to specific spacetimes like deSitter, cylinder, and Minkowski.

Abstract

The regularized expectation value of the stress-energy tensor for a massless bosonic or fermionic field in 1+1 dimensions is calculated explicitly for the instantaneous vacuum relative to any Cauchy surface (here a spacelike curve) in terms of the length L of the curve (if closed), the local extrinsic curvature K of the curve, its derivative K' with respect to proper distance x along the curve, and the scalar curvature R of the spacetime: T_{00} = - epsilon pi/(6L^2) - K^2/(24 pi), T_{01} = - K'/(12 pi), T_{11} = - epsilon pi/(6L^2) - K^2/(24 pi) + R/(24 pi), in an orthonormal frame with the spatial vector parallel to the curve. Here epsilon = 1 for an untwisted (i.e., periodic in x) one-component massless bosonic field or for a twisted (i.e., antiperiodic in x) two-component massless fermionic field, epsilon = -1/2 for a twisted one-component massless bosonic field, and epsilon = - 2 for an untwisted two-component massless fermionic field. The calculation uses merely the energy-momentum conservation law and the trace anomaly (for which a very simple derivation is also given herein, as well as the expression for the Casimir energy of bosonic and fermionic fields twisted by an arbitrary amount in R^{D-1} x S^1). The two coordinate and conformal invariants of a quantum state that are (nonlocally) determined by the stress-energy tensor are given. Applications to topologically modified deSitter spacetimes, to a flat cylinder, and to Minkowski spacetime are discussed.