Topologically protected optical polarization singularities in four-dimensional space

Christina M. Spaegele; Michele Tamagnone; Soon Wei Daniel Lim; Marcus Ossiander; Maryna L. Meretska; Federico Capasso

doi:10.1126/sciadv.adh0369

Topologically protected optical polarization singularities in four-dimensional space

Christina M. Spaegele
, Michele Tamagnone
, Soon Wei Daniel Lim
, Marcus Ossiander
, Maryna L. Meretska
, Federico Capasso

Research output: Contribution to journal › Article › peer-review

Abstract

Optical singularities play a major role in modern optics and are frequently deployed in structured light, superresolution microscopy, and holography. While phase singularities are uniquely defined as locations of undefined phase, polarization singularities studied thus far are either partial, i.e., bright points of well-defined polarization, or are unstable for small field perturbations. We demonstrate a complete, topologically protected polarization singularity; it is located in the four-dimensional space spanned by the three spatial dimensions and the wavelength and is created in the focus of a cascaded metasurface-lens system. The field Jacobian plays a key role in the design of such higher-dimensional singularities, which can be extended to multidimensional wave phenomena, and pave the way for unconventional applications in topological photonics and precision sensing.

Original language	English
Article number	eadh0369
Journal	Science Advances
Volume	9
Issue number	24
DOIs	https://doi.org/10.1126/sciadv.adh0369
Publication status	Published - 16 Jun 2023
Externally published	Yes

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Advanced Materials Science

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10.1126/sciadv.adh0369Licence: CC BY-NC 4.0

Cite this

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title = "Topologically protected optical polarization singularities in four-dimensional space",

abstract = "Optical singularities play a major role in modern optics and are frequently deployed in structured light, superresolution microscopy, and holography. While phase singularities are uniquely defined as locations of undefined phase, polarization singularities studied thus far are either partial, i.e., bright points of well-defined polarization, or are unstable for small field perturbations. We demonstrate a complete, topologically protected polarization singularity; it is located in the four-dimensional space spanned by the three spatial dimensions and the wavelength and is created in the focus of a cascaded metasurface-lens system. The field Jacobian plays a key role in the design of such higher-dimensional singularities, which can be extended to multidimensional wave phenomena, and pave the way for unconventional applications in topological photonics and precision sensing.",

author = "Spaegele, \{Christina M.\} and Michele Tamagnone and Lim, \{Soon Wei Daniel\} and Marcus Ossiander and Meretska, \{Maryna L.\} and Federico Capasso",

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AU - Spaegele, Christina M.

AU - Tamagnone, Michele

AU - Lim, Soon Wei Daniel

AU - Ossiander, Marcus

AU - Meretska, Maryna L.

AU - Capasso, Federico

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PY - 2023/6/16

Y1 - 2023/6/16

N2 - Optical singularities play a major role in modern optics and are frequently deployed in structured light, superresolution microscopy, and holography. While phase singularities are uniquely defined as locations of undefined phase, polarization singularities studied thus far are either partial, i.e., bright points of well-defined polarization, or are unstable for small field perturbations. We demonstrate a complete, topologically protected polarization singularity; it is located in the four-dimensional space spanned by the three spatial dimensions and the wavelength and is created in the focus of a cascaded metasurface-lens system. The field Jacobian plays a key role in the design of such higher-dimensional singularities, which can be extended to multidimensional wave phenomena, and pave the way for unconventional applications in topological photonics and precision sensing.

AB - Optical singularities play a major role in modern optics and are frequently deployed in structured light, superresolution microscopy, and holography. While phase singularities are uniquely defined as locations of undefined phase, polarization singularities studied thus far are either partial, i.e., bright points of well-defined polarization, or are unstable for small field perturbations. We demonstrate a complete, topologically protected polarization singularity; it is located in the four-dimensional space spanned by the three spatial dimensions and the wavelength and is created in the focus of a cascaded metasurface-lens system. The field Jacobian plays a key role in the design of such higher-dimensional singularities, which can be extended to multidimensional wave phenomena, and pave the way for unconventional applications in topological photonics and precision sensing.

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DO - 10.1126/sciadv.adh0369

M3 - Article

SN - 2375-2548

VL - 9

JO - Science Advances

JF - Science Advances

IS - 24

M1 - eadh0369

ER -

Topologically protected optical polarization singularities in four-dimensional space

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