Polarization Stop Bands in Chiral Polymeric Three‐Dimensional Photonic Crystals

Thiel, Michael; Decker, Manuel; Deubel, M.; Wegener, Martin; Lindén, Stefan; Freymann, Georg von

doi:10.1002/adma.200601497

Cited by 138 publications

(119 citation statements)

References 18 publications

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“…The effect has enormous importance for analytical chemistry, crystallography, molecular biology, and the food industry and is also a signature effect used to detect life forms in space missions. The recognition of chirality as a source negative refraction of light [1][2][3][4][5][6] needed for the creation of a perfect lens [7] inspired intense work in developing microwave and optical artificial chiral metamaterials [8][9][10][11][12] and yielded a demonstration of negative index due to chirality [8,13]. In this paper we present a somewhat surprising result that very strong optical activity may be seen in a metamaterial system consisting of meta-molecules that itself are not chiral.…”

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confidence: 90%

“…differential absorbtion for left and right circular polarizations. The recent effort in creating artificial optically active metamaterials that aimed to achieve strong optical activity was focused on different types of arrays of 3D-chiral meta-molecules [8][9][10][11][12][14][15][16][17]. It is significantly less acknowledged that optical activity can also be seen when oriented non-chiral molecules make a chiral triad with the wave vector of light.…”

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Metamaterials: Optical Activity without Chirality

et al. 2009

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We report that the classical phenomenon of optical activity, which is traditionally associated with chirality (helicity) of organic molecules, proteins and inorganic structures, can be observed in artificial media which exhibit neither volume nor planar chirality (helicity). We have designed a metamaterial film periodically structured on the subwavelength scale which behaves indistinguishably from chiral three-dimensional media yielding strong circular dichroism and birefringence in transmission for waves incident at oblique angles.The phenomenon of optical activity that is the ability to rotate the polarization state of light is a fundamental effect of electrodynamics which is traditionally associated with mirror asymmetry (chirality) of organic molecules. The effect has enormous importance for analytical chemistry, crystallography, molecular biology, and the food industry and is also a signature effect used to detect life forms in space missions. The recognition of chirality as a source negative refraction of light [1-6] needed for the creation of a perfect lens [7] inspired intense work in developing microwave and optical artificial chiral metamaterials [8][9][10][11][12] and yielded a demonstration of negative index due to chirality [8,13]. In this paper we present a somewhat surprising result that very strong optical activity may be seen in a metamaterial system consisting of meta-molecules that itself are not chiral. Here chirality is drawn from the mutual orientation of the wave propagation direction and the two-dimensional metamaterial. We demonstrate the optical activity effect using an artificially created non-chiral planar metamaterial structure and show that it behaves indistinguishably from chiral three-dimensional molecular systems manifesting resonant birefringence and dichroism for circularly polarized electromagnetic waves.Through the efforts of several generations of researchers optical activity was linked to the threedimensional property of molecules known as chirality: a molecular structure such as a helix for which mirror images are not congruent possesses a sufficient asymmetry to manifest polarization rotation (optical activity). The effect of optical activity is linked to the phenomenon of circular dichroism, i.e. differential absorbtion for left and right circular polarizations. The recent effort in creating artificial optically active metamaterials that aimed to achieve strong optical activity was focused on different types of arrays of 3D-chiral meta-molecules [8][9][10][11][12][14][15][16][17]. It is significantly less acknowledged that optical activity can also be seen when oriented non-chiral molecules make a chiral triad with the wave vector of light. This mechanism of optical activity was first described by Bunn [18] and detected in liquid crystals [19]. Here we show that this is a highly significant mechanism of optical activity in metamaterials that can be seen as essentially planar structures that possess neither 2D chirality [20,21] nor FIG. 1: (Color online) Planar slit m...

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Metamaterials: Optical Activity without Chirality

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“…[3][4][5][6][7][8][9] Although not widely known, optical activity in the form of circular birefringence and dichroism can also be observed in extrinsically chiral systems. In such a system a non-chiral structure together with the incident wave forms a geometrical arrangement that cannot be superimposed with its mirror image and thus the whole arrangement is chiral.…”

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Optical activity in extrinsically chiral metamaterial

Plum

Fedotov

Zheludev

2008

Applied Physics Letters

264

182

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We demonstrate optical activity in an intrinsically non-chiral anisotropic planar metamaterial. The phenomenon is due to extrinsic chirality resulting from the mutual orientation of the metamaterial structure and the incident electromagnetic wave. The polarization effect, which has a resonant nature, features a spectral band where linear birefringence is practically absent and can be easily tuned by tilting the plane of the metamaterial relative to the incident beam. © 2008 American Institute of Physics. ͓DOI: 10.1063/1.3021082͔Recent predictions that strong optical activity could result in a negative index of refraction 1,2 inspired intense work on developing artificial three-dimensionally ͑3D͒ chiral metamaterials, i.e., arrays of identical meta-molecules, where the meta-molecules themselves are different from their mirror image and therefore intrinsically 3D-chiral. [3][4][5][6][7][8][9] Although not widely known, optical activity in the form of circular birefringence and dichroism can also be observed in extrinsically chiral systems. In such a system a non-chiral structure together with the incident wave forms a geometrical arrangement that cannot be superimposed with its mirror image and thus the whole arrangement is chiral. This mechanism of polarization rotation was first identified by Bunn 10 and has been observed in liquid crystals. 11 In this letter we show that extrinsic chirality is a highly significant source of optical activity in metamaterials. We demonstrate strong polarization rotary power and circular dichroism at oblique incidence in a planar metamaterial, which is neither two-dimensionally ͑2D͒ chiral 12,13 nor 3D-chiral. The effect is inherently tunable: its sign and magnitude are controlled by the tilt of the metamaterial plane relative to the incident beam. Importantly, this type of tunable optical activity occurs in simple planar metamaterial designs that are ideally suited for well-established planar manufacturing technologies.We studied optical activity in a planar metamaterial structure consisting of a regular 2D array of metal split rings supported by a 1.6 mm thick dielectric substrate ͑see Fig. 1͒. The rings were split asymmetrically into pairs of arcs of different lengths separated by equal gaps. Each split ring had a line of mirror symmetry but had no axis of twofold rotation. The planar metamaterial sample was approximately 220ϫ 220 mm 2 large and had a square unit cell of 15ϫ 15 mm 2 , which ensured no diffraction at normal or oblique incidence for frequencies below 10 GHz. Our measurements were performed in an anechoic chamber using microwave broadband horn antennas ͑Schwarzbeck BBHA 9120D͒ equipped with lens concentrators and a vector network analyzer ͑Agilent E8364B͒. We measured losses and phase delays for circularly polarized waves transmitted by the metamaterial at various angles of incidence in the range from −30°to +30°achieved by tilting the sample around its symmetry axis. In practical terms we measured the complex transmission matrix E i out = t ij E j in relating the...

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“…51 Wegener and co-workers pioneered the use of DLW TPL and double inversion to generate "woodpile" PhC architectures that contain defect cavities and act as resonators. 58 Direct laser writing also enables the fabrication of arbitrarily complex micro-and nanostructures and has been exploited to generate chiral PhCs with polarization stopbands 59 and 3D photonic quasicrystals 60 that exhibit novel photonic properties not available in strictly periodic structures. Fabrication and characterization of tunable 3D PhCs is an area of increasing research interest.…”

Section: Nanolattices Prepared By Direct-laser-writing Twophoton Lithmentioning

confidence: 99%

Materials by design: Using architecture in material design to reach new property spaces

2015

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MATERIALS BY DESIGN: USING ARCHITECTURE IN MATERIAL DESIGN TO REACH NEW PROPERTY SPACES 1123MRS BULLETIN • VOLUME 40 • DECEMBER 2015 • www.mrs.org/bulletin S Similarly, phononic crystals (PnCs) are artifi cial periodic structures composed of elastic materials, in which mechanical waves within a specifi c frequency bandwidth are forbidden from propagating. This prohibited frequency range is termed the phononic bandgap (PnBG) and enables sound, and often heat, to be controlled, allowing for the creation of more effi cient fi lters, waveguides, and resonant cavities.The combination of geometry-including lattice type, topology, and scale-with material properties determines the ultimate behavior of architected materials. Beyond controlling wave propagation and mechanical properties, structural design and microstructural parameters are signifi cant for many applications, including battery electrodes, supercapacitors, and other electrochemical (e.g., electrochromic) devices.

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Polarization Stop Bands in Chiral Polymeric Three‐Dimensional Photonic Crystals

Cited by 138 publications

References 18 publications

Metamaterials: Optical Activity without Chirality

Metamaterials: Optical Activity without Chirality

Optical activity in extrinsically chiral metamaterial

Materials by design: Using architecture in material design to reach new property spaces

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