Abstract:Abstract:Quantum entanglement of two photons created by spontaneous parametric downconversion (SPDC) can be used to probe quantum optical phenomena during a single cycle of light. Harris [Phys. Rev. Lett. 98, 063602 (2007)] suggested using ultrabroad parametric fluorescence generated from a quasi-phase-matched (QPM) device whose poling period is chirped. In the Harris's original proposal, it is assumed that the photons are collinearly generated and then spatially separated by frequency filtering. Here, we alt… Show more
“…In these schemes, the photon flux of the light source can be much higher compared to QOCT, but the realized bandwidth of the correlated light source seems much broader in QOCT [27]. Research using these alternative approaches will have beneficial positive mutual feedback for further investigations.…”
The dispersion cancellation observed in Hong-Ou-Mandel (HOM) interference between frequency-entangled photon pairs has been the basis of quantum optical coherence tomography and quantum clock synchronization. Here we explore the effect of phase dispersion on ultranarrow HOM dips. We show that the higher-order dispersion, the linewidth of the pump laser, and the spectral shape of the parametric fluorescence have a strong effect on the dispersion cancellation in the high-resolution regime with several experimental verifications. Perfect dispersion cancellation with a linewidth of 3 μm is also demonstrated through 25 mm of water.
“…In these schemes, the photon flux of the light source can be much higher compared to QOCT, but the realized bandwidth of the correlated light source seems much broader in QOCT [27]. Research using these alternative approaches will have beneficial positive mutual feedback for further investigations.…”
The dispersion cancellation observed in Hong-Ou-Mandel (HOM) interference between frequency-entangled photon pairs has been the basis of quantum optical coherence tomography and quantum clock synchronization. Here we explore the effect of phase dispersion on ultranarrow HOM dips. We show that the higher-order dispersion, the linewidth of the pump laser, and the spectral shape of the parametric fluorescence have a strong effect on the dispersion cancellation in the high-resolution regime with several experimental verifications. Perfect dispersion cancellation with a linewidth of 3 μm is also demonstrated through 25 mm of water.
“…This offers a hyperentangled version of the original proposal by Harris 43 to generate temporally entangled photon pairs correlated to less than one cycle of light. A superlattice chirp-and-compress design will generate noncollinear ultra-broadband biphotons with no need for large chirping 44, 45 and no need for self-compensation to eliminate temporal distinguishability, and hence no need for an additional time-delay element.…”
Section: Discussionmentioning
confidence: 99%
“…Each of the two orthogonal sets of nonlinear layers acts like spacers that engineer the group-delay 38, 39 of the emission of the other set. QPM is woven into each of the orthogonally polarized emissions, and as in other SPDC processes it enables access to the highest nonlinear coefficient, opens the possibility for tunability with highly reduced bandwidth over a wide spectral range 40 , and offers a unique capability of tailoring the spatiotemporal properties of the entangled photons 41–45 . In comparison with the CC source and the DN source, this superlattice (SL) structure is shown to emit SPDC biphotons with nearly perfect spatial and temporal indistinguishability over ultra-wide spatial and spectral windows, even if it uses a focused and low-coherence-time beam to pump a long structure in a noncollinear interaction geometry, and without the need for compensating elements.Figure 1( a) Schematic of the superlattice structure showing the two interleaved sets of nonlinear layers with orthogonal optic axes and orthogonal directions of poling, as indicated by the g
H ( z ) and g
V ( z ) functions.…”
A crystal superlattice structure featuring nonlinear layers with alternating orthogonal optic axes interleaved with orthogonal poling directions, is shown to generate high-quality hyperentangled photon pairs via orthogonal quasi-phase-matched spontaneous parametric downconversion. We demonstrate that orthogonal quasi-phase matching (QPM) processes in a single nonlinear domain structure correct phase and group-velocity mismatches concurrently. Compared with the conventional two-orthogonal-crystals source and the double-nonlinearity single-crystal source, the orthogonal QPM superlattice is shown to suppress the spatial and temporal distinguishability of the generated photon pairs by several orders of magnitude, depending on the number of layers. This enhanced all-over-the-cone indistinguishability enables the generation of higher fluxes of photon-pairs by means of the combined use of (a) long nonlinear crystal in noncollinear geometry, (b) low coherence-time pumping and ultra-wide-band spectral detection, and (c) focused pumping and over-the-cone detection. While each of these three features is challenging by itself, it is remarkable that the orthogonal QPM superlattice meets all of these challenges without the need for separate spatial or temporal compensation.
“…The temperature increase is characterized by phase-matched calorimetry (PMC) [1,2], which analyzes the performance of the heat removal in the module. Combination of Mg:SLT and a metal heat spreader realizes stable output in green, which is also useful in green-pumped optical parametric generation for obtaining stable quantum-entangled photon pairs [3,4].…”
Thermal management is discussed in single-pass CW SHG in QPM Mg:SLT. Effective heat capacity in four-side heat removal module is quantitatively characterized by Phase-Matched Calorimetry and enhanced by 50% with narrowing device width.
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