Direct generation of genuine single-longitudinal-mode narrowband photon pairs

TL;DR

This paper presents an integrated, miniaturized photon pair source with a narrow bandwidth and high purity, suitable for quantum communication, achieved through a specialized waveguide design and spectral clustering.

Contribution

The authors develop a stable, integrated single-longitudinal-mode narrowband photon pair source with high brightness and spectral purity, advancing practical quantum communication technologies.

Findings

Achieved a narrow 60 MHz bandwidth for photon pairs.

Demonstrated high brightness of 3×10^4 pairs/(s·mW·MHz).

Observed coherence time longer than single-photon states.

Abstract

The practical prospect of quantum communication and information processing relies on sophisticated single photon pairs which feature controllable waveform, narrow spectrum, excellent purity, fiber compatibility and miniaturized design. For practical realizations, stable, miniaturized, low-cost devices are required. Sources with one or some of above performances have been demonstrated already, but it is quite challenging to have a source with all of the described characteristics simultaneously. Here we report on an integrated single-longitudinal-mode non-degenerate narrowband photon pair source, which exhibits all requirements needed for quantum applications. The device is composed of a periodically poled Ti-indiffused lithium niobate waveguide with high reflective dielectric mirror coatings deposited on the waveguide end-faces. Photon pairs with wavelengths around 890 nm and 1320 nm are generated via type II phase-matched parametric down-conversion. Clustering in this dispersive cavity restricts the whole conversion spectrum to one single-longitudinal-mode in a single cluster yielding a narrow bandwidth of only 60 MHz. The high conversion efficiency in the waveguide, together with the spectral clustering in the doubly resonant waveguide, leads to a high brightness of $3\times10^4~$pairs/(s$\cdot$mW$\cdot$MHz). This source exhibits prominent single-longitudinal-mode purity and remarkable temporal shaping capability. Especially, due to temporal broadening, we can observe that the coherence time of the two-photon component of PDC state is actually longer than the one of the single photon states. The miniaturized monolithic design makes this source have various fiber communication applications.