{"id":354581,"date":"2025-11-04T08:26:19","date_gmt":"2025-11-04T08:26:19","guid":{"rendered":"https:\/\/www.europesays.com\/us\/354581\/"},"modified":"2025-11-04T08:26:19","modified_gmt":"2025-11-04T08:26:19","slug":"electrically-tuning-photonic-topological-quasiparticles-in-synthetic-two-level-system","status":"publish","type":"post","link":"https:\/\/www.europesays.com\/us\/354581\/","title":{"rendered":"Electrically tuning photonic topological quasiparticles in synthetic two-level system"},"content":{"rendered":"
  • \n

    Skyrme, T. H. R. A non-linear field theory. Proc. R. Soc. A 260<\/b>, 127\u2013138 (1961).<\/p>\n

    ADS<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Skyrme, T. H. R. A unified field theory of mesons and baryons. Nucl. Phys. 31<\/b>, 556\u2013569 (1962).<\/p>\n

    Article<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Nagaosa, N. & Tokura, Y. Topological properties and dynamics of magnetic skyrmions. Nat. Nanotechnol. 8<\/b>, 899\u2013911 (2013).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y. et al. Optical skyrmions and other topological quasiparticles of light. Nat. Photonics 18<\/b>, 15\u201325 (2024).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Chong, A., Wan, C., Chen, J. & Zhan, Q. Generation of spatiotemporal optical vortices with controllable transverse orbital angular momentum. Nat. Photonics 14<\/b>, 350\u2013354 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Wan, C., Cao, Q., Chen, J., Chong, A. & Zhan, Q. Toroidal vortices of light. Nat. Photonics 16<\/b>, 519\u2013522 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Song, K. M. et al. Skyrmion-based artificial synapses for neuromorphic computing. Nat. Electron. 3<\/b>, 148\u2013155 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    G\u00f6bel, B., Mertig, I. & Tretiakov, O. A. Beyond skyrmions: review and perspectives of alternative magnetic quasiparticles. Phys. Rep. 895<\/b>, 1\u201328 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Seki, S. & Mochizuki, M. Skyrmions in Magnetic Materials (Springer, 2016).<\/p>\n<\/li>\n

  • \n

    Tokura, Y. & Kanazawa, N. Magnetic skyrmion materials. Chem. Rev. 121<\/b>, 2857\u20132897 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Kent, N. et al. Creation and observation of hopfions in magnetic multilayer systems. Nat. Commun. 12<\/b>, 1562 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Zheng, F. et al. Hopfion rings in a cubic chiral magnet. Nature 623<\/b>, 718\u2013723 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Romming, N. et al. Writing and deleting single magnetic skyrmions. Science 341<\/b>, 636\u2013639 (2013).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Yu, G. et al. Room-temperature skyrmion shift device for memory application. Nano Lett. 17<\/b>, 261\u2013268 (2017).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Maccariello, D. et al. Electrical detection of single magnetic skyrmions in metallic multilayers at room temperature. Nat. Nanotechnol. 13<\/b>, 233\u2013237 (2018).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Raftrey, D. & Fischer, P. Field-driven dynamics of magnetic hopfions. Phys. Rev. Lett. 127<\/b>, 257201 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Jiang, W. et al. Direct observation of the skyrmion Hall effect. Nat. Phys. 13<\/b>, 162\u2013169 (2017).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Litzius, K. et al. Skyrmion Hall effect revealed by direct time-resolved X-ray microscopy. Nat. Phys. 13<\/b>, 170\u2013175 (2017).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Yang, S. et al. Reversible conversion between skyrmions and skyrmioniums. Nat. Commun. 14<\/b>, 3406 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Zheng, F. et al. Skyrmion\u2013antiskyrmion pair creation and annihilation in a cubic chiral magnet. Nat. Phys. 18<\/b>, 863\u2013868 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Fert, A., Reyren, N. & Cros, V. Magnetic skyrmions: advances in physics and potential applications. Nat. Rev. Mater. 2<\/b>, 1\u201315 (2017).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Han, L. et al. High-density switchable skyrmion-like polar nanodomains integrated on silicon. Nature 603<\/b>, 63\u201367 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y. et al. Optical vortices 30 years on: OAM manipulation from topological charge to multiple singularities. Light Sci. Appl. 8<\/b>, 90 (2019).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Forbes, A., De Oliveira, M. & Dennis, M. R. Structured light. Nat. Photonics 15<\/b>, 253\u2013262 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Gao, S. et al. Paraxial skyrmionic beams. Phys. Rev. A 102<\/b>, 053513 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Ni, J. et al. Multidimensional phase singularities in nanophotonics. Science 374<\/b>, eabj0039 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Wang, H., Shi, L., Lukyanchuk, B., Sheppard, C. & Chong, C. T. Creation of a needle of longitudinally polarized light in vacuum using binary optics. Nat. Photonics 2<\/b>, 501\u2013505 (2008).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Tsesses, S. et al. Optical skyrmion lattice in evanescent electromagnetic fields. Science 361<\/b>, 993\u2013996 (2018).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Davis, T. J. et al. Ultrafast vector imaging of plasmonic skyrmion dynamics with deep subwavelength resolution. Science 368<\/b>, eaba6415 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Bai, C., Chen, J., Zhang, Y., Zhang, D. & Zhan, Q. Dynamic tailoring of an optical skyrmion lattice in surface plasmon polaritons. Opt. Express 28<\/b>, 10320\u201310328 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Dai, Y. et al. Plasmonic topological quasiparticle on the nanometre and femtosecond scales. Nature 588<\/b>, 616\u2013619 (2020).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Du, L., Yang, A., Zayats, A. V. & Yuan, X. Deep-subwavelength features of photonic skyrmions in a confined electromagnetic field with orbital angular momentum. Nat. Phys. 15<\/b>, 650\u2013654 (2019).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Yang, A. et al. Spin-manipulated photonic skyrmion-pair for pico-metric displacement sensing. Adv. Sci. 10<\/b>, 2205249 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Lei, X. et al. Photonic spin lattices: symmetry constraints for skyrmion and meron topologies. Phys. Rev. Lett. 127<\/b>, 237403 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Karnieli, A., Tsesses, S., Bartal, G. & Arie, A. Emulating spin transport with nonlinear optics, from high-order skyrmions to the topological Hall effect. Nat. Commun. 12<\/b>, 1092 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Wang, H. & Fan, S. Photonic spin hopfions and monopole loops. Phys. Rev. Lett. 131<\/b>, 263801 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y., Hou, Y., Papasimakis, N. & Zheludev, N. I. Supertoroidal light pulses as electromagnetic skyrmions propagating in free space. Nat. Commun. 12<\/b>, 5891 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y. et al. Topologically controlled multiskyrmions in photonic gradient-index lenses. Phys. Rev. Appl. 21<\/b>, 024025 (2024).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Wang, S. et al. Topological structures of energy flow: Poynting vector skyrmions. Phys. Rev. Lett. 133<\/b>, 073802 (2024).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Lin, Y. J., Compton, R. L., Jim\u00e9nez-Garc\u00eda, K., Porto, J. V. & Spielman, I. B. Synthetic magnetic fields for ultracold neutral atoms. Nature 462<\/b>, 628\u2013632 (2009).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Zhang, Y., Tan, Y. W., Stormer, H. L. & Kim, P. Experimental observation of the quantum Hall effect and Berry\u2019s phase in graphene. Nature 438<\/b>, 201\u2013204 (2005).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Xiao, M. et al. Geometric phase and band inversion in periodic acoustic systems. Nat. Phys. 11<\/b>, 240\u2013244 (2015).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Yale, C. G. et al. Optical manipulation of the Berry phase in a solid-state spin qubit. Nat. Photonics 10<\/b>, 184\u2013189 (2016).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Wang, J. et al. Experimental observation of Berry phases in optical M\u00f6bius-strip microcavities. Nat. Photonics 17<\/b>, 120\u2013125 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Karnieli, A., Li, Y. & Arie, A. The geometric phase in nonlinear frequency conversion. Front. Phys. 17<\/b>, 12301 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Cohen, E. et al. Geometric phase from Aharonov\u2013Bohm to Pancharatnam\u2013Berry and beyond. Nat. Rev. Phys. 1<\/b>, 437\u2013449 (2019).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Karnieli, A. & Arie, A. Fully controllable adiabatic geometric phase in nonlinear optics. Opt. Express 26<\/b>, 4920\u20134932 (2018).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Scully, M. O., Lamb, W. E. Jr. & Barut, A. On the theory of the Stern\u2013Gerlach apparatus. Found. Phys. 17<\/b>, 575\u2013583 (1987).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Chen, G. et al. Advances in lithium niobate photonics: development status and perspectives. Adv. Photonics 4<\/b>, 034003 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Fu, S. et al. Spin-orbit optical Hall effect. Phys. Rev. Lett. 123<\/b>, 243904 (2019).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Zhang, X. et al. Photonic spin-orbit coupling induced by deep-subwavelength structured light. Phys. Rev. A 109<\/b>, 023522 (2024).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Feynman, R. P., Vernon, F. L. Jr. & Hellwarth, R. W. Geometrical representation of the Schr\u00f6dinger equation for solving Maser problems. J. Appl. Phys. 28<\/b>, 49\u201352 (1957).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Hahn, E. L. Nuclear induction due to free Larmor precession. Phys. Rev. 77<\/b>, 297\u2013298 (1950).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Berry, M. V. The adiabatic phase and Pancharatnam\u2019s phase for polarized light. J. Mod. Opt. 34<\/b>, 1401\u20131407 (1987).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n     MathSciNet<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Karnieli, A., Trajtenberg-Mills, S., Di Domenico, G. & Arie, A. Experimental observation of the geometric phase in nonlinear frequency conversion. Optica 6<\/b>, 1401\u20131405 (2019).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Suchowski, H., Porat, G. & Arie, A. Adiabatic processes in frequency conversion. Laser Photonics Rev. 8<\/b>, 333\u2013367 (2014).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Yesharim, O. et al. Observation of the all-optical Stern\u2013Gerlach effect in nonlinear optics. Nat. Photonics 16<\/b>, 582\u2013587 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Karnieli, A. & Arie, A. All-optical Stern-Gerlach Effect. Phys. Rev. Lett. 120<\/b>, 053901 (2018).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Voloch-Bloch, N., Lereah, Y., Lilach, Y., Gover, A. & Arie, A. Generation of electron Airy beams. Nature 494<\/b>, 331\u2013335 (2013).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Ornelas, P., Nape, I., de Koch, M. R. & Forbes, A. Non-local skyrmions as topologically resilient quantum entangled states of light. Nat. Photonics 18<\/b>, 258\u2013266 (2024).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Gottesman, D. & Chuang, I. Demonstrating the viability of universal quantum computation using teleportation and single-qubit operations. Nature 402<\/b>, 390\u2013393 (1999).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y., Mart\u00ednez, E. C. & Rosales-Guzm\u00e1n, C. Generation of optical skyrmions with tunable topological textures. ACS Photonics 9<\/b>, 296\u2013303 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Shen, Y. et al. Topological transformation and free-space transport of photonic hopfions. Adv. Photonics 5<\/b>, 015001 (2023).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Sugic, D. et al. Particle-like topologies in light. Nat. Commun. 12<\/b>, 6785 (2021).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Lee, W. H. Binary computer-generated holograms. Appl. Opt. 18<\/b>, 3661\u20133669 (1979).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Hu, X. B. & Rosales-Guzmn, C. Generation and characterization of complex vector modes with digital micromirror devices: a tutorial. J. Opt. 24<\/b>, 034001 (2022).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Zhan, Q. Cylindrical vector beams: from mathematical concepts to applications. Adv. Opt. Photonics 1<\/b>, 1\u201357 (2009).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
    \n Google Scholar<\/a>\u00a0\n <\/p>\n<\/li>\n

  • \n

    Berry, H. G., Gabrielse, G. & Livingston, A. E. Measurement of the Stokes parameters of light. Appl. Opt. 16<\/b>, 3200\u20133205 (1977).<\/p>\n

    Article<\/a>\u00a0
    \n     ADS<\/a>\u00a0
    \n
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