2022
DOI: 10.22331/q-2022-02-09-646
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Resolution of Quantum Imaging with Undetected Photons

Abstract: Quantum imaging with undetected photons is a recently introduced technique that goes significantly beyond what was previously possible. In this technique, images are formed without detecting the light that interacted with the object that is imaged. Given this unique advantage over the existing imaging schemes, it is now of utmost importance to understand its resolution limits, in particular what governs the maximal achievable spatial resolution. We show both theoretically and experimentally that the momentum … Show more

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Cited by 33 publications
(39 citation statements)
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“…Although the presented analysis focuses on QIUP based on position correlations, the same fundamental diffraction limit applies to the setup based on momentum correlations since the change of the optical elements cannot affect the limited range of transverse momenta of propagated photons. The difference between the achievable resolution in the two schemes based on position correlations and momentum correlations occurs only within the paraxial regime (thick crystals), where the minimum resolvable distance for the latter is d min ∝ λ I /σ P , with σ P as the transverse width of the pump [7,20]. However, in the non-paraxial limit, the imaging resolution of both cases will be restricted by the limited range of transverse momenta that can be generated by a photon-pair source.…”
Section: Discussion and Summarymentioning
confidence: 99%
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“…Although the presented analysis focuses on QIUP based on position correlations, the same fundamental diffraction limit applies to the setup based on momentum correlations since the change of the optical elements cannot affect the limited range of transverse momenta of propagated photons. The difference between the achievable resolution in the two schemes based on position correlations and momentum correlations occurs only within the paraxial regime (thick crystals), where the minimum resolvable distance for the latter is d min ∝ λ I /σ P , with σ P as the transverse width of the pump [7,20]. However, in the non-paraxial limit, the imaging resolution of both cases will be restricted by the limited range of transverse momenta that can be generated by a photon-pair source.…”
Section: Discussion and Summarymentioning
confidence: 99%
“…Considering that the path of the idler photons are aligned, see Eq. (20), and signal photons of both sources interfere q S,A = q S,B = q S , then the state of the system can be written as…”
Section: Appendix B: Minimum Resolvable Distance In the Paraxial Regimementioning
confidence: 99%
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“…This allows analytically calculating the limits of some properties of an interferometer. [155,164] Effects such as misalignment of the optical system diminish the quality of the interferometer output. One cause is the variation of phase shifts within the idler distribution p(k i ; k s ).…”
Section: Simulation Of Nonlinear Interferometersmentioning
confidence: 99%
“…We use the term "far-field" in contrast to "near-field", where nearfield interactions can involve evanescent modes and are usually only effective within wavelength-range distances [13]. Hence, resolution of far-field QIUP will be constrained by the diffraction limit [4,[14][15][16]. For the case where the probing wavelength λ I is larger than the detection wavelength λ S , object's information is transferred by propagating idler fields and consequently the transverse spatial resolution in this information is constrained by the idler diffraction limit [14].…”
mentioning
confidence: 99%