The $i\varepsilon$-Prescription for String Amplitudes and Regularized Modular Integrals

TL;DR

This paper introduces an $i ext{-}oldsymbol{ extepsilon}$-prescription for string theory integrals, providing a regularization method that yields exact and numerically accessible expressions for one-loop amplitudes, aligning with recent contour approaches.

Contribution

It establishes an $i ext{-}oldsymbol{ extepsilon}$-prescription for string amplitudes, connecting it to generalized exponential integral regularization and demonstrating agreement with recent contour methods.

Findings

Exact expressions for one-loop amplitudes in terms of mass level degeneracies

Closed-form imaginary parts of amplitudes derived

Numerical evaluation of real parts facilitated

Abstract

We study integrals appearing in one-loop amplitudes in string theory, and in particular their analytic continuation based on a string theoretic analog of the $i\varepsilon$-prescription of quantum field theory. For various zero- and two-point one-loop amplitudes of both open and closed strings, we prove that this analytic continuation is equivalent to a regularization using generalized exponential integrals. Our approach provides exact expressions in terms of the degeneracies at each mass level. For one-loop amplitudes with boundaries, our result takes the form of a linear combination of three partition functions at different temperatures depending on a variable $T_0$, yet their sum is independent of this variable. The imaginary part of the amplitudes can be read off in closed form, while the real part is amenable to numerical evaluation. While the expressions are rather different, we demonstrate agreement of our approach with the contour put forward by Eberhardt-Mizera (2023) following the Hardy-Ramanujan-Rademacher circle method.