2013
DOI: 10.1103/physrevlett.110.203903
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Full Control of Nanoscale Optical Transmission with a Composite Metascreen

Abstract: By applying the optical nanocircuit concepts to metasurfaces, we propose an effective route to locally control light transmission over a deeply subwavelength scale. This concept realizes the optical equivalent of a transmit-array, whose use is demonstrated for light bending and focusing with unprecedented efficiency over a subwavelength distance, with crucial benefits for nano-optics applications. These findings may lead to large improvements in the manipulation of optical transmission and processing of nanosc… Show more

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Cited by 760 publications
(658 citation statements)
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References 27 publications
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“…May we still obtain the desired parameter values by properly combining and sculpting the two given constituent materials with different parameters, particularly when the desired parameter values are vastly different from those of the constituent materials? Indeed, this quest is consistent with the notion of metamaterials, and many examples of metamaterials constructed in the past decade by various research groups worldwide have been built using a limited number of materials [17][18][19][20][21][22][23][24] . However, here we develop the notion of digital metamaterials in order to demonstrate that with only two properly chosen elemental materials, coined as "metamaterial bits", at a given range of operating wavelengths, one would, under proper conditions, be able to synthesize composite media with a large range of parameter values.…”
Section: Main Textsupporting
confidence: 56%
“…May we still obtain the desired parameter values by properly combining and sculpting the two given constituent materials with different parameters, particularly when the desired parameter values are vastly different from those of the constituent materials? Indeed, this quest is consistent with the notion of metamaterials, and many examples of metamaterials constructed in the past decade by various research groups worldwide have been built using a limited number of materials [17][18][19][20][21][22][23][24] . However, here we develop the notion of digital metamaterials in order to demonstrate that with only two properly chosen elemental materials, coined as "metamaterial bits", at a given range of operating wavelengths, one would, under proper conditions, be able to synthesize composite media with a large range of parameter values.…”
Section: Main Textsupporting
confidence: 56%
“…Generally speaking, metasurfaces function as interface discontinuities which, depending on size, shape and composition of scatterers, allow for an abrupt change in the amplitude and/or phase of the impinging light. 7 It should be noted that a single layer of scatterers (due to their Lorentzian-shaped polarizability) only allow for full 2π-phase control of the cross-polarized light component, 8 meaning that such metasurfaces have a theoretical efficiency of maximum 25%, 9 though most realizations show efficiencies of a few percent. 10,11 In order to improve the efficiency of plasmonic metasurfaces, the low-frequency concept of transmit-and reflectarrays has been generalized and adopted to the visible and infrared regimes, where metasurfaces working in transmission consist of several layers in order to reach full phase control and proper impedance matching with surroundings.…”
mentioning
confidence: 99%
“…Metatronic concepts have provided a useful theoretical framework connecting plasmonics, metamaterials and nanophotonics with conventional electronics [2][3][4][5] . These ideas have guided the efficient design of metasurfaces 6,7 and the modelling of a variety of composite nanostructures, including plasmonic NP clusters [8][9][10] , NP rings exhibiting strong optical magnetism 11 and microcavity lasers 12 . However, the direct application of these concepts to photonic circuits has so far been limited to modelling and tuning optical nanoantennas [13][14][15][16][17][18][19] , and to realizing a ladder network of two-dimensional (2D) nanoinductors and nanocapacitors in the form of a subwavelength grating at mid-infrared frequencies 4 .…”
mentioning
confidence: 99%