Which Functions Admit a Positive Geometry? From Branch Cuts to String Amplitudes
Hyungrok Kim, Jonah Stalknecht
Abstract
Positive geometry provides a geometric framework where physical observables are encoded as canonical forms associated to regions of kinematic space. In this paper we consider a generalisation to an infinite union of line segments, which allows us to capture canonical forms beyond rational functions. In the continuum limit of positive geometries, we show that we can generalise even further and describe positive geometries whose canonical forms contain branch cuts. We will constrain which functions can be obtained as the canonical form of one-dimensional positive geometries. We introduce the notion of the pseudogenus to classify meromorphic functions, and show that canonical forms can be written as the $\mathrm d\log$ of a function with pseudogenus zero. Furthermore, we argue that the spectrum encoded by a union of line segments is consistent with the presence of a stringy tower of states or a Kaluza-Klein tower with three or more compact directions only if nearly all such states do not contribute to the scattering amplitude. In addition, we show how the d log of both open and closed string amplitudes admits a positive geometry. This allows us to give a fully geometric interpretation for the KLT double copy at four points.