Temporally-long C-band heralded single photons generated from hot atoms

TL;DR

This paper presents a theoretical and experimental study of long-duration C-band heralded single photons generated from hot atoms, achieving the longest temporal width recorded for atom-based sources in this wavelength range.

Contribution

It introduces a new theoretical model for biphoton generation via SFWM in hot atoms and demonstrates the longest temporal width for C-band heralded single photons from hot atomic sources.

Findings

Achieved 28.3 ns temporal width for C-band heralded single photons.

Developed a theoretical model aligning with experimental data.

First to exceed 10 ns in temporal width for atom-based sources in this wavelength range.

Abstract

C-band photons are recognized for having the lowest loss coefficient in optical fibers, making them highly favorable for optical fiber-based communication. In this study, we systematically investigated the temporal width of C-band heralded single photons and developed a theoretical model for biphoton generation via the spontaneous four-wave mixing (SFWM) process using a diamond-type transition scheme, which has not been previously reported. Our experimental data on temporal width closely aligns with the predictions of this model. Additionally, we introduced a new concept: the atomic velocity group relating to the two-photon resonance condition and the one-photon detuning in this atomic frame. These two parameters are crucial for understanding the behavior of the biphoton source. The concept indicates that the hot-atom source behaves similarly to the cold-atom source. Guided by our theoretical model, we observed 1529-nm (C-band) heralded single photons with a temporal width of 28.3$\pm$0.6 ns, corresponding to a linewidth of 11.0$\pm$0.2 MHz. For comparison, the ultimate linewidth limit is 6.1 MHz, determined by the natural linewidth of the atoms. Among all atom-based sources of 1300 to 1550 nm heralded single photons utilizing either cold or hot atoms, the temporal width achieved in this work represents the first instance of a width exceeding 10 ns, making it (or its linewidth) the longest (or narrowest) record to date. This work significantly enhances our understanding of diamond-type or cascade-type SFWM biphoton generation and marks an important milestone in achieving greater temporal width in atom-based sources of C-band heralded single photons.