Enhancement of the photon pair generation rate by spontaneous four-wave mixing in bent waveguides

TL;DR

This paper demonstrates that moderate bending of waveguides can significantly enhance photon pair generation rates via spontaneous four-wave mixing, due to improved mode localization despite increased losses.

Contribution

It reveals that waveguide bending can increase nonlinear efficiency by reducing mode area, providing a new design strategy for integrated quantum photonic devices.

Findings

Optimal bending radii improve generation rate by up to 270%.

Bending enhances effective nonlinearity through mode localization.

Waveguide bending offers a compact way to boost quantum optical device performance.

Abstract

Enhancing nonlinear optical effects is critical to improving the performance of many functional devices for nonlinear and quantum optical applications. Here we study the possibility of bending a waveguide to enhance the photon pair generation rate in a spontaneous four-wave mixing process. Whereas intuition might suggest that bending makes the process less efficient, because the waveguides are more lossy when bent, we show that the increase in the effective nonlinearity outperforms the disadvantage for moderate bending radii. That can be explained by a better localization of the guided eigenmodes, leading to a reduced mode area. By studying selected waveguide devices with a fixed length, we demonstrate an optimal improvement between 5 % and 270 % in the photon pair generation rate for an optimal bending radius. These findings have implications for the future design of integrated photonic devices for quantum optical applications, especially in cases where the chip estate tends to be a limiting factor.