Some variations of the reduction of one-loop Feynman tensor integrals

Abstract

We present a new algorithm for the reduction of one-loop tensor Feynman integrals with n≤ 4 external legs to scalar Feynman integrals InD with n=3,4 legs in D dimensions, where D=d+2l with integer l ≥ 0 and generic dimension d=4-2ε, thus avoiding the appearance of inverse Gram determinants ()4. As long as ()4≠ 0, the integrals I3,4D with D>d may be further expressed by the usual dimensionally regularized scalar functions I2,3,4d. The integrals I4D are known at ()4 0, so that we may extend the numerics to small, non-vanishing ()4 by applying a dimensional recurrence relation. A numerical example is worked out. Together with a recursive reduction of 6- and 5-point functions, derived earlier, the calculational scheme allows a stabilized reduction of n-point functions with n≤ 6 at arbitrary phase space points. The algorithm is worked out explicitely for tensors of rank R≤ n.