Casimir interaction of finite-width strings

Within the trln-formalism we investigate the vacuum interaction of cosmic strings and the influence of strings width on this effect. For the massless real scalar field we compute the Casimir contribution into the total vacuum energy. The dimensional-regularization technique is used. It is shown that the regularized Casimir term contains neither the UV-divergences, nor the divergences related with the non-integrability of the renormalized vacuum mean of the energy-momentum tensor.Comment: 3 figure

Vacuum polarization and classical self-action near higher-dimensional defects

We analyze the gravity-induced effects associated with a massless scalar field in a higher-dimensional spacetime being the tensor product of $$(d-n)$$-dimensional Minkowski space and n-dimensional spherically/cylindrically symmetric space with a solid/planar angle deficit. These spacetimes are considered as simple models for a multidimensional global monopole (if $$n\geqslant 3$$) or cosmic string (if $$n=2$$) with $$(d-n-1)$$ flat extra dimensions. Thus, we refer to them as conical backgrounds. In terms of the angular-deficit value, we derive the perturbative expression for the scalar Green function, valid for any $$d\geqslant 3$$ and $$2\leqslant n\leqslant d-1$$, and compute it to the leading order. With the use of this Green function we compute the renormalized vacuum expectation value of the field square $${\langle \phi ^{{}2}(x)\rangle }_{\mathrm{ren}}$$ and the renormalized vacuum averaged of the scalar-field energy-momentum tensor $${\langle T_{M N}(x)\rangle }_{\mathrm{ren}}$$ for arbitrary d and n from the interval mentioned above and arbitrary coupling constant to the curvature $$\xi$$. In particular, we revisit the computation of the vacuum polarization effects for a non-minimally coupled massless scalar field in the spacetime of a straight cosmic string. The same Green function enables to consider the old purely classical problem of the gravity-induced self-action of a classical point-like scalar or electric charge, placed at rest at some fixed point of the space under consideration. To deal with divergences, which appear in consideration of the two problems, we apply the dimensional-regularization technique, widely used in quantum field theory. The explicit dependence of the results upon the dimensionalities of both the bulk and conical submanifold is discussed