Photon-pair generation by non-instantaneous spontaneous four-wave mixing

TL;DR

This paper develops a comprehensive Hamiltonian-based model for photon-pair generation via pulsed spontaneous four-wave mixing, accounting for nonlinear effects and finite response times, and explores how these factors influence photon purity and production rates.

Contribution

It introduces a novel analytical and numerical framework that includes nonlinear phase modulation and finite material response, advancing understanding of photon-pair generation in silica fibers.

Findings

Pair-production rate weakly depends on temperature due to Raman scattering.

Purity of heralded photons varies significantly with pump pulse duration and detuning.

Numerical simulations reveal impact of non-instantaneous response on photon purity.

Abstract

We present a general model, based on a Hamiltonian approach, for the joint quantum state of photon pairs generated through pulsed spontaneous four-wave mixing, including nonlinear phase-modulation and a finite material response time. For the case of a silica fiber, it is found that the pair-production rate depends weakly on the waveguide temperature, due to higher-order Raman scattering events, and more strongly on pump-pair frequency detuning. From the analytical model, a numerical scheme is derived, based on the well-known split-step method. This scheme allows computation of joint states where nontrivial effects are included, such as group-velocity dispersion and Raman scattering. In this work, the numerical model is used to study the impact of the non-instantaneous response on the pre-filtering purity of heralded single photons. We find that for pump pulses shorter than 1 ps, a significant detuning-dependent change in quantum-mechanical purity may be observed in silica.