The vacuum energy with non-ideal boundary conditions via an approximate functional equation

Abstract

We discuss the vacuum energy of a quantized scalar field in the presence of classical surfaces, defining bounded domains ⊂ Rd, where the field satisfies ideal or non-ideal boundary conditions. For the electromagnetic case, this situation describes the conductivity correction to the zero-point energy. Using an analytic regularization procedure, we obtain the vacuum energy for a massless scalar field at zero temperature in the presence of a slab geometry = Rd-1×[0, L] with Dirichlet boundary conditions. To discuss the case of non-ideal boundary conditions, we employ an asymptotic expansion, based on an approximate functional equation for the Riemann zeta-function, where finite sums outside their original domain of convergence are defined. Finally, to obtain the Casimir energy for a massless scalar field in the presence of a rectangular box, with lengths L1 and L2, i.e., =[0,L1]×[0,L2] with non-ideal boundary conditions, we employ an approximate functional equation of the Epstein zeta-function.