Improving spatial resolution in quantum imaging beyond the Rayleigh diffraction limit using multiphoton W entangled states
Wen, J.; Du, S.; Xiao, M.
Physics Letters A 374(38): 3908-3911
2010
ISSN/ISBN: 0375-9601 DOI: 10.1016/j.physleta.2010.07.068
Accession: 084710540
Full-Text Article emailed within 0-6 h
Payments are secure & encrypted
References
Prasad, S.; Owens, J.R.; Bray, J.; Neculaes, V.B. 2022: Quantum limited superresolution – imaging beyond the Rayleigh diffraction limit Proceedings of SPIE - The International Society for Optical Engineering 12016: 120160KPeacock, A.C.; Steel, M.J. 2016: QUANTUM OPTICS. the time is right for multiphoton entangled states Science 351(6278): 1152-1153
Zhu, P.; Xue, S.; Zheng, Q.; Wu, C.; Yu, X.; Wang, Y.; Liu, Y.; Qiang, X.; Deng, M.; Wu, J.; Xu, P. 2020: Reconfigurable multiphoton entangled states based on quantum photonic chips Optics Express 28(18): 26792-26806
Reimer, C.; Kues, M.; Roztocki, P.; Wetzel, B.; Grazioso, F.; Little, B.E.; Chu, S.T.; Johnston, T.; Bromberg, Y.; Caspani, L.; Moss, D.J.; Morandotti, R. 2016: Generation of multiphoton entangled quantum states by means of integrated frequency combs Science 351(6278): 1176-1180
Zatovskij, A.V.; Ivanov, V.G.; Rogovskaya Eh, T.; Salistra, G.I. 1988: Limitations de diffraction sur la résolution spatiale limite et la limite de grande longueur d'onde des récepteurs IR monolithiques à faible absorption - Diffraction limitations on spatial resolution limit and long wavelength limit of low absorption monolithic IR receptors Zurnal Tehniceskoj Fiziki 58(10): 1871-1877
Denning, E.V.; Iles-Smith, J.; McCutcheon, D.P.S.; Mork, J. 2017: Protocol for generating multiphoton entangled states from quantum dots in the presence of nuclear spin fluctuations Physical Review A 96(6): 062329
Amooei, M.; Kulkarni, G.; Upham, J.; Boyd, R.W. 2025: Efficient characterization of spatial Schmidt modes of multiphoton entangled states produced from high-gain parametric down-conversion Physical Review A 111(2): 023714
Wieczorek, W.; Kiesel, N.; Schmid, C.; Laskowski, W.; Zukowski, M.; Weinfurter, H. 2009: Multiphoton Interference as a Tool to Observe Families of Multiphoton Entangled States IEEE Journal of Selected Topics in Quantum Electronics 15(6): 1704-1712
Li, L.; Li, F. 2013: Beating the Rayleigh limit: orbital-angular-momentum-based super-resolution diffraction tomography Physical Review. e Statistical Nonlinear and Soft Matter Physics 88(3): 033205
Asban, S.; Dorfman, K.E.; Mukamel, S. 2019: Quantum phase-sensitive diffraction and imaging using entangled photons Proceedings of the National Academy of Sciences of the United States of America 116(24): 11673-11678
Reintjes, J.F.; Bashkansky, M. 2019: Spatial resolution in entangled ghost imaging Proceedings of SPIE - The International Society for Optical Engineering 10984: 109840H
Reintjes, J.; Bashkansky, M. 2019: Spatial and temporal resolution in entangled ghost imaging Journal of Modern Optics 66(16): 1668-1677
Torres, J.P.; Carrasco, S.; Osorio, C.I.; Torner, L. 2004: Quantum engineering for spatial control of entangled two-photon states Optics InfoBase Conference Papers: FMC4
Maslova, N.S.; Mantsevich, V.N.; Arseyev, P.I.; Sokolov, I.M. 2022: Spatial transfer of entangled states in the correlated quantum dots system Laser Physics Letters 19(5): 055208
Rosen, J.; Siegel, N.; Brooker, G. 2011: Theoretical and experimental demonstration of resolution beyond the Rayleigh limit by FINCH fluorescence microscopic imaging Optics Express 19(27): 26249-26268
Tokuhisa, A.; Taka, J.; Kono, H.; Go, N. 2012: Classifying and assembling two-dimensional X-ray laser diffraction patterns of a single particle to reconstruct the three-dimensional diffraction intensity function: resolution limit due to the quantum noise Acta Crystallographica. Section A Foundations of Crystallography 68(Pt 3): 366-381
Krivanek, O.L.; Bleloch, A.L.; Dellby, N.; Lovejoy, T.C.; Shi, C.; Zhou, W. 2018: Improving the Stem Spatial Resolution Limit Microscopy and Microanalysis 24(S1): 18-19
Rempe, G. 1995: One atom in an optical cavity: Spatial resolution beyond the standard diffraction limit Applied Physics B Laser and Optics 60(2-3): 233-237
Decking, U.K.M.; Pai, V.M.; Bennett, E.; Taylor, J.L.; Fingas, C.D.; Zanger, K.; Wen, H.; Balaban, R.S. 2004: High-resolution imaging reveals a limit in spatial resolution of blood flow measurements by microspheres American Journal of Physiology. Heart and Circulatory Physiology 287(3): H1132-H1140
Balakin, D.A.; Belinsky, A.V. 2022: Quantum ghost imaging with improved diffraction limit Quantum Information Processing 21(7): 251