Casimir effect in Lorentz-violating scalar field theory: a local approach

Abstract

We study the Casimir effect in the classical geometry of two parallel conductive plates, separated by a distance L, for a Lorentz-breaking extension of the scalar field theory. The Lorentz-violating part of the theory is characterized by the term λ ( u · ∂ φ )2, where the parameter λ and the background four-vector u μ codify Lorentz symmetry violation. We use Green's function techniques to study the local behavior of the vacuum stress-energy tensor in the region between the plates. Closed analytical expressions are obtained for the Casimir energy and pressure. We show that the energy density EC (and hence the pressure) can be expressed in terms of the Lorentz-invariant energy density E0 as follows align EC (L) = 1-λ un 21 + λ u 2 E0 (L) , align where L = L / 1-λ un 2 is a rescaled plate-to-plate separation and un is the component of u along the normal to the plates. As usual, divergences of the local Casimir energy do not contribute to the pressure.