One-loop stress-tensor renormalization in curved background: the relation between ζ-function and point-splitting approaches, and an improved point-splitting procedure
Abstract
We conclude the rigorous analysis of a previous paper concerning the relation between the (Euclidean) point-splitting approach and the local ζ-function procedure to renormalize physical quantities at one-loop in (Euclidean) QFT in curved spacetime. The stress tensor is now considered in general D-dimensional closed manifolds for positive scalar operators - + V(x). Results obtained in previous works (in the case D=4 and V(x) = R(x) + m2) are rigorously proven and generalized. It is also proven that, in static Euclidean manifolds, the method is compatible with Lorentzian-time analytic continuations. It is found that, for D>1, the result of the ζ function procedure is the same obtained from an improved version of the point-splitting method which uses a particular choice of the term w0(x,y) in the Hadamard expansion of the Green function. This point-splitting procedure works for any value of the field mass m. Furthermore, in the case D=4 and V(x) = R(x)+ m2, the given procedure generalizes the Euclidean version of Wald's improved point-splitting procedure. The found point-splitting method should work generally, also dropping the hypothesis of a closed manifold, and not depending on the ζ-function procedure. This fact is checked in the Euclidean section of Minkowski spacetime for A = - + m2 where the method gives rise to the correct stress tensor for m2 ≥ 0 automatically.
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