Nature-inspired chiral metasurfaces for circular polarization detection and full-Stokes polarimetric measurements

Basiri, Ali; Chen, Xiahui; Bai, Jing; Amrollahi, Pouya; Carpenter, Joseph A.; Holman, Zachary C.; Wang, Chao; Yao, Yu

doi:10.1038/s41377-019-0184-4

Cited by 223 publications

(159 citation statements)

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“…Surface plasmons, collective electron density oscillations at dielectric/ metal interfaces, [26][27][28][29][30] can dramatically enhance chiroptical responses by concentrating far-field electromagnetic waves into subwavelength volumes. [31][32][33][34][35][36][37] Over the past decade, many studies have demonstrated the feasibility of transferring molecular chirality to plasmonic nanostructures, [16,18,19,38,39] opening up a plethora of possibilities for chiral biosensing and bioimaging with unprecedented detection limits ideally down to the singlemolecule regime. A primary driving force behind this development is the breakthrough in design and fabrication of artificial metallic nanostructures, ranging from top-down techniques such as focused ion beam milling, [40] electron-beam lithography [41] and direct laser writing, [42] to bottom-up methods like chemical synthesis and self-assembly.…”

Section: Introductionmentioning

confidence: 99%

Chirality Transfer from Sub‐Nanometer Biochemical Molecules to Sub‐Micrometer Plasmonic Metastructures: Physiochemical Mechanisms, Biosensing, and Bioimaging Opportunities

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Chirality Transfer from Sub‐Nanometer Biochemical Molecules to Sub‐Micrometer Plasmonic Metastructures: Physiochemical Mechanisms, Biosensing, and Bioimaging Opportunities

et al. 2020

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“…Chiral metamaterials and metasurfaces [1][2][3][4][5] have recently attracted much attention in the community of nanophotonics due to their practical applications for circular dichroism (CD), [6][7][8][9][10][11] polarization conversion, [12] chiral biosensing and imaging, [13][14][15] polarimetric detection, [16] spin-controlled wavefront shaping, [17,18] and asymmetric transmission. [10,18,19] Spin-selective optical responses can also be obtained in intrinsically achiral metasurfaces due to extrinsic chirality by the experimental arrangement different from their mirror image [20] and even by the direct phase modulation depending on the handedness of circular polarization of the incident wave.…”

Section: Introductionmentioning

confidence: 99%

Dielectric Chiral Metasurfaces for Second‐Harmonic Generation with Strong Circular Dichroism

Kim

2020

Annalen der Physik

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Dielectric chiral metasurfaces can generate harmonic waves with high efficiency and strong circular dichroism (CD), when they are supported by metallic substrates. Numerical results show that the second-harmonic generation (SHG) efficiency of about 10 −3 % for a peak pump intensity of about 5 GW cm −2 can be achieved in the blue-UV, and the SHG CD reaches up to about 1.8, from a metasurface of Z-shaped lithium niobate nanoantenna array supported by gold substrate. Highly efficient and strong circular dichroic nonlinear responses are attributed to the plasmon-assisted local field enhancement in the dielectric chiral nanoantennae adjacent to the metallic substrate.

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“…The second example is by Shi et al [186] who studied the silver ants living in the Saharan desert and developed an idea of a biomimetic metasurface-based coating for the passive effective cooling of objects. The third example is by Basiri et al [187] who designed a metasurface-based polarization filter device inspired by the polarization sensing of the compound eyes of mantis shrimps. The peak extinction ratio of the metasurface device could reach a value of 35, and transmission efficiency was close to 80% in the near-infrared wavelength region.…”

Section: Future Directionsmentioning

confidence: 99%

Metasurfaces for biomedical applications: imaging and sensing from a nanophotonics perspective

et al. 2020

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Metasurface is a recently developed nanophotonics concept to manipulate the properties of light by replacing conventional bulky optical components with ultrathin (more than 104 times thinner) flat optical components. Since the first demonstration of metasurfaces in 2011, they have attracted tremendous interest in the consumer optics and electronics industries. Recently, metasurface-empowered novel bioimaging and biosensing tools have emerged and been reported. Given the recent advances in metasurfaces in biomedical engineering, this review article covers the state of the art for this technology and provides a comprehensive interdisciplinary perspective on this field. The topics that we have covered include metasurfaces for chiral imaging, endoscopic optical coherence tomography, fluorescent imaging, super-resolution imaging, magnetic resonance imaging, quantitative phase imaging, sensing of antibodies, proteins, DNAs, cells, and cancer biomarkers. Future directions are discussed in twofold: application-specific biomedical metasurfaces and bioinspired metasurface devices. Perspectives on challenges and opportunities of metasurfaces, biophotonics, and translational biomedical devices are also provided. The objective of this review article is to inform and stimulate interdisciplinary research: firstly, by introducing the metasurface concept to the biomedical community; and secondly by assisting the metasurface community to understand the needs and realize the opportunities in the medical fields. In addition, this article provides two knowledge boxes describing the design process of a metasurface lens and the performance matrix of a biosensor, which serve as a “crash-course” introduction to those new to both fields.

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Nature-inspired chiral metasurfaces for circular polarization detection and full-Stokes polarimetric measurements

Cited by 223 publications

References 50 publications

Chirality Transfer from Sub‐Nanometer Biochemical Molecules to Sub‐Micrometer Plasmonic Metastructures: Physiochemical Mechanisms, Biosensing, and Bioimaging Opportunities

Chirality Transfer from Sub‐Nanometer Biochemical Molecules to Sub‐Micrometer Plasmonic Metastructures: Physiochemical Mechanisms, Biosensing, and Bioimaging Opportunities

Dielectric Chiral Metasurfaces for Second‐Harmonic Generation with Strong Circular Dichroism

Metasurfaces for biomedical applications: imaging and sensing from a nanophotonics perspective

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