Related papers: Generation of photon pairs through spontaneous four-wave mixing in thin nonlinear layers

Generation of photon pairs through spontaneous four-wave mixing in thin nonlinear layers

URL: http://arxiv.org/abs/2502.01305v1
Date: Mon, 03 Feb 2025 12:30:06 GMT
Title: Generation of photon pairs through spontaneous four-wave mixing in thin nonlinear layers
Authors: Changjin Son, Samuel Peana, Owen Matthiessen, Artem Kryvobok, Alexander Senichev, Alexandra Boltasseva, Vladimir M. Shalaev, Maria Chekhova,
Abstract summary: Pairs of entangled photons are a key resource for photonic quantum technologies. Despite the success in the demonstration of spontaneous parametric-down-conversion (SPDC), there are almost no works on spontaneous four-wave mixing (SFWM) SFWM can be implemented in any nanostructures, including isotropic and centrosymmetric ones.
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Abstract: Pairs of entangled photons are a key resource for photonic quantum technologies. The demand for integrability and multi-functionality suggests flat platforms, such as ultrathin layers and metasurfaces, as sources of photon pairs. Despite the success in the demonstration of spontaneous parametric-down-conversion (SPDC) from such flat sources, there are almost no works on spontaneous four-wave mixing (SFWM) - an alternative process to generate photon pairs. Meanwhile, SFWM can be implemented in any nanostructures, including isotropic and centrosymmetric ones, which are easier to fabricate than crystalline structures needed for SPDC. Here, we investigate photon pair generation through SFWM in subwavelength layers of amorphous silicon nitride (SiN) and study the effect of nitrogen content on the rate of pair emission. By observing two-photon interference between SFWM from the SiN layers and from the fused silica substrate, we find the third-order susceptibilities of layers with different nitrogen content. Finally, we demonstrate SFWM in lithium niobate, which is a second-order nonlinear material and where the direct SFWM can coexist with a cascaded process. Our results open a path for the implementation of SFWM in resonant flat structures, such as metasurfaces.

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