Maximizing the Validity of the Gaussian Approximation for the biphoton State from Parametric Downconversion

Abstract

Spontaneous parametric down-conversion (SPDC) is widely used in quantum applications based on photonic entanglement. The efficiency of photon pair generation is often characterized by means of a sinc(L k/2)-function, where L is the length of the nonlinear medium and k the phase mismatch between the pump and down-converted fields. In theoretical investigations, the sinc behavior of the phase mismatch has often been approximated by a Gaussian function (-α x2) in order to derive analytical expressions for the SPDC process. Different values have been chosen in the literature for the optimization factor α, for instance by comparing the widths of sinc and Gaussian functions or the momentum of down-converted photons. As a consequence, different values for α provide different theoretical predictions for the same setup. Therefore, an informed and unique choice of this parameter is necessary. In this work, we present a choice of α which maximizes the validity of the Gaussian approximation. Moreover, we also discuss the so-called super-Gaussian and cosine-Gaussian approximations as practical alternatives with improved predictive power for experiments.