Photon-pair generation by intermodal spontaneous four-wave mixing in birefringent, weakly guiding optical fibers

Garay-Palmett, Karina; Cruz-Delgado, Daniel; Domínguez-Serna, Francisco A.; Ortiz-Ricardo, E.; Monroy-Ruz, Jorge; Cruz-Ramírez, Héctor; Alarcón, Roberto Ramírez; U’Ren, Alfred B.

doi:10.1103/physreva.93.033810

Cited by 34 publications

(25 citation statements)

References 36 publications

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“…Let us note that with M supported modes, in principle M 4 processes are possible, which in our case (M = 6) translates into 1296 processes. As we discussed in Ref., 34 Fig. 4 (d),(g),(j), the slight shift is probably due to calibration error in the monochromators.…”

Section: Discussionsupporting

confidence: 57%

“…In order to analyze our experimental results, we consider a fiber that supports the linearly polarized modes LP 01 and LP 11 ; fiber birefringence then implies the existence of two non-degenerate LP 01 modes: LP 01x and LP 01y , polarized along the x and y directions, and four non-degenerate LP 11 modes: LP 11ex , LP 11ey , LP 11ox , and LP 11oy , with even(e) and odd(o) parity. 33 We have used a simple dispersion model where, for polarization i = x, y and parity j = e, o, the index of refraction is given as n i j (ω) = n(ω) + δ ix ∆ + δ jo ∆ p , where δ i j is a Kronecker delta; here, n(ω) is obtained for a step-index fiber characterized by radius r and numerical aperture NA, while ∆ is the birefringence and ∆ p is the "parity birefringence" 34 (with ∆ p = n xo − n xe = n yo − n ye ).…”

Section: Discussionmentioning

confidence: 99%

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Fiber-based photon-pair source capable of hybrid entanglement in frequency and transverse mode, controllably scalable to higher dimensions

Cruz-Delgado

Alarcón

Ortiz-Ricardo

et al. 2016

Sci Rep

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We have designed and implemented a photon-pair source, based on the spontaneous four wave mixing (SFWM) process in a few-mode fiber, in a geometry which permits multiple, simultaneous SFWM processes, each associated with a distinct combination of transverse modes for the four participating waves. In our source: i) each process is group-velocity-matched so that it is, by design, nearly-factorable, and ii) the spectral separation between neighboring processes is greater than the marginal spectral width of each process. Consequently, there is a direct correspondence between the joint amplitude of each process and each of the Schmidt mode pairs of the overall two-photon state. Our approach permits hybrid entanglement in discrete frequency and in transverse mode, whereby control of the number of supported fiber transverse modes allows scalability to higher dimensions while spectral filtering may be used for straightforward Schmidt mode discrimination.

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Section: Discussionsupporting

confidence: 57%

Section: Discussionmentioning

confidence: 99%

Fiber-based photon-pair source capable of hybrid entanglement in frequency and transverse mode, controllably scalable to higher dimensions

Cruz-Delgado

Alarcón

Ortiz-Ricardo

et al. 2016

Sci Rep

Self Cite

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“…Another interesting possibility is for the four waves to propagate in different transverse modes (in a fewmode or multi-mode fiber), likewise leading to an offset of the generation frequencies from the pump frequencies. Thus, let us discuss the case of CP-SFWM implemented in a few-mode optical fiber [33,34] leading to an intermodal process; this means allowing some of the waves involved in the SFWM process to travel in higher-order transverse modes. As an example, if the forward propagating pump travels in the fundamental fiber mode and the signal photon travels in a certain higher-order mode X, while the backward-propagating pump mode travels in the same higher-order mode X and the idler photon travels in the fundamental mode, then perfect phasematching will occur for signal and idler frequencies that are shifted from those of the pumps.…”

Section: Phasematching Properties and Sfwm-pump Discriminationmentioning

confidence: 99%

Counter-propagating spontaneous four wave mixing: photon-pair factorability and ultra-narrowband single photons

2016

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We introduce a new kind of spontaneous four wave mixing process for the generation of photon pairs, in which the four waves involved counter-propagate in a guided-wave c ( ) 3 medium; we refer to this process as counter-propagating spontaneous four wave mixing (CP-SFWM). We show that for the simplest CP-SFWM source, in which all waves propagate in the same polarization and transverse mode and in which self-and cross-phase modulation effects are negligible, phasematching is attained automatically regardless of dispersion in the fiber or waveguide. Furthermore, we show that in two distinct versions of this source (both pumps pulsed, or one pump pulsed and the remaining one monochromatic), the two-photon state is automatically factorable provided that the length of the nonlinear medium exceeds a certain threshold, easily achievable in practice since this threshold length tends to be in the range of mm to cm. We also show that if one of the pumps approaches the monochromatic limit, and for a sufficient nonlinear medium length, the bandwidth of one of the two photons in a given pair may be reduced to the level of MHz, compatible with electronic transitions for the implementation of atom-photon interfaces, without the use of optical cavities.

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“…In addition, we would like to mention several review papers and overview articles covering topics that are touched on here but are beyond the scope of this review: single photon sources and detectors, integrated‐optical sources of entangled photons, and generation of photon pairs via spontaneous four wave mixing …”

Section: Introductionmentioning

confidence: 99%

Perspectives for Applications of Quantum Imaging

Basset

Setzpfandt

Steinlechner

et al. 2019

Laser & Photonics Reviews

111

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Quantum imaging is a multifaceted field of research that promises highly efficient imaging in extreme spectral ranges as well as ultralow‐light microscopy. Since the first proof‐of‐concept experiments over 30 years ago, the field has evolved from highly fascinating academic research to the verge of demonstrating practical technological enhancements in imaging and microscopy. Here, the aim is to give researchers from outside the quantum optical community, in particular those applying imaging technology, an overview of several promising quantum imaging approaches and evaluate both the quantum benefit and the prospects for practical usage in the near future. Several use case scenarios are discussed and a careful analysis of related technology requirements and necessary developments toward practical and commercial application is provided.

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Photon-pair generation by intermodal spontaneous four-wave mixing in birefringent, weakly guiding optical fibers

Cited by 34 publications

References 36 publications

Fiber-based photon-pair source capable of hybrid entanglement in frequency and transverse mode, controllably scalable to higher dimensions

Fiber-based photon-pair source capable of hybrid entanglement in frequency and transverse mode, controllably scalable to higher dimensions

Counter-propagating spontaneous four wave mixing: photon-pair factorability and ultra-narrowband single photons

Perspectives for Applications of Quantum Imaging

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