Narrow-band photon pair generation through cavity-enhanced spontaneous parametric down-conversion

Amideddin Mataji-Kojouri and Marco Liscidini

Phys. Rev. A 108, 053714 – Published 20 November 2023

Abstract

Cavity-enhanced spontaneous parametric down-conversion (SPDC) can be used to implement heralded single-photon sources with narrow bandwidth down to tens of megahertz, thus compatible with atom-based quantum memories. In this work, we propose and study the cavities that are either singly resonant at the frequency of only one of the generated photons or doubly resonant at the frequency of one generated photon and for the pump field. We derive analytical expressions for the generation rate and the spectral brightness as a function of the main structure parameters. Our analysis shows that by exploiting counterpropagating SPDC inside a cavity with properly designed distributed Bragg reflectors, pure narrow-band heralded single photons can be generated. In particular, when a pulsed pump illuminates a 1-mm-long singly resonant cavity, the bandwidth of the resonant and the nonresonant photons will be 120 MHz and 5.7 GHz, respectively, with heralded single-photon purity as high as 0.993. Due to its small absorption probability inside the cavity, the heralding efficiency can approach unity if the nonresonant partner is used as a heralded single photon. Finally, we also show that continuous-wave excitation of a 1-cm-long cavity resonant for the pump and copropagating fields can provide photon pairs in a narrow bandwidth of 10 MHz with spectral brightness as high as $2 \times 10^{6}$ $({s mW MHz)}^{- 1}$ . This source can efficiently couple with quantum memories and can find applications in quantum information processing and communication.

Received 27 June 2023
Accepted 18 October 2023

DOI:https://doi.org/10.1103/PhysRevA.108.053714

Physics Subject Headings (PhySH)

Optical quantum information processing Photon pairs & parametric down-conversion Quantum communication Quantum optics Quantum state engineering

Atomic, Molecular & Optical

Authors & Affiliations

Amideddin Mataji-Kojouri and Marco Liscidini ^*

Dipartimento di Fisica, Università di Pavia, Via Agostino Bassi 6, 27100 Pavia, Italy

^*marco.liscidini@unipv.it

Article Text (Subscription Required)

Click to Expand

References (Subscription Required)

Click to Expand

Issue

Vol. 108, Iss. 5 — November 2023

Reuse & Permissions

Access Options

Author publication services for translation and copyediting assistance advertisement

Images

Figure 1
A monolithic photon-pair source based on cavity-enhanced SPDC. The cavity is formed by depositing dielectric mirrors at the end facets of a periodically poled ${LiNbO}_{3}$ substrate. A hypothetical waveguide region is shown by dashed lines. The cavity is resonant for pump and signal fields and there is an additional dielectric mirror for the idler field on the left side to ensure idler photons exit only from the right side. Mirrors are designed so that the pump field is critically coupled on the left side and the signal field is so on the right side. Other mirrors are highly reflective to eliminate unwanted scattering losses.
Reuse & Permissions
Figure 2
(a) Reflection spectra of the right ( $R_{R}$ ) and left ( $R_{L}$ ) dielectric mirrors. The left mirror is designed to critically couple the pump field but totally reflect the signal field. On the contrary, the right mirror has a very high reflectivity at the pump frequency and critically couples the signal field to the output. Reflection from the cavity near the pump (incident from left) (b), signal (incident from right) (c), and idler (incident from right) (d) frequencies. No resonances are visible in the reflection spectrum around the idler frequency. Magnified view of the reflection spectra at pump (e) and signal (f) frequencies.
Reuse & Permissions
Figure 3
Joint spectral amplitude calculated numerically for the mirror stacks with reflection spectra shown in Fig. 2, when the crystal is periodically poled for copropagating (a) and counterpropagating (b) idler fields. In the case of the copropagating idler field, the spectrum is comblike for both signal and idler frequency ranges despite the idler field being nonresonant. For the counterpropagating idler field, the spectrum displays only one resonance due to the narrow-band phase-matching condition.
Reuse & Permissions
Figure 4
Left axis: Photon-pair generation rate calculated numerically or using the analytical formula as provided in the text for a Fabry-Pérot cavity enclosing a ${LiNbO}_{3}$ crystal of length $L$ between 0.1 and 2 cm formed by distributed Bragg reflector stacks with their respective reflectivity shown in Fig. 2. Right axis: Spectral brightness of the source predicted analytically.
Reuse & Permissions
Figure 5
(a) Superimposed surface plots as functions of signal and idler photon frequencies showing the phase-matching function (green color map), the pulse amplitude (red color map), and the field amplitude enhancement (yellow color map) for a crystal length of $L = 1$ mm. For this graph, a relatively small mirror reflectivity ( $| r_{L, ω_{P}} |^{2} = {| r_{R, ω_{S}} |}^{2} = 0.4$ ) is used for better visibility. Factorizable JSA with purity near unity for a pump pulse with $τ_{d} = 200$ ps when the pump field is either nonresonant (b) or resonant (c). The bandwidth of the signal photon can be directly controlled by the reflectivity of the mirror at the signal frequency. As for the idler, the photon bandwidth can be controlled to a degree by the cavity for the pump field and the state remains factorizable if $Δ ω_{P} ≪ Δ ω_{S}$ .
Reuse & Permissions

Physical Review A

covering atomic, molecular, and optical physics and quantum information