2018
DOI: 10.1088/1361-6463/aaf11b
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Photonic demultiplexer based on electromagnetically induced transparency resonances

Abstract: We give an analytical and experimental demonstration of the possibility to realize a simple photonic demultiplexer based on electromagnetically induced transparency resonances. The demultiplexer consists of a Y-shaped waveguide with an input line and two output lines. Each output line contains two grafted stubs at a given position far from the input line. We derive in closed form the expressions for a selective transfer of a single propagating mode through one line keeping the other line unaffected. We illustr… Show more

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Cited by 19 publications
(13 citation statements)
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“…These results show that the lengths of asymmetric resonators constituting the electromagnetic demultiplexer should be chosen appropriately in order to transfer a frequency in one transmission line by keeping the other transmission line unaffected. This type of resonance mode has already been found for a phononic and photonic demultiplexer with two channels, and each channel is composed of one segment and two asymmetric resonators [30][31][32]. These resonance modes are wide, i.e., low quality factor Q (calculated from Q = Ω/∆Ω where Ω is the central frequency of the mode, and ∆Ω is the width to half height of this mode) which can be considered poor in terms of signal guiding and filtering [24].…”
Section: Demultiplexer Based On Large Resonance Modessupporting
confidence: 53%
See 1 more Smart Citation
“…These results show that the lengths of asymmetric resonators constituting the electromagnetic demultiplexer should be chosen appropriately in order to transfer a frequency in one transmission line by keeping the other transmission line unaffected. This type of resonance mode has already been found for a phononic and photonic demultiplexer with two channels, and each channel is composed of one segment and two asymmetric resonators [30][31][32]. These resonance modes are wide, i.e., low quality factor Q (calculated from Q = Ω/∆Ω where Ω is the central frequency of the mode, and ∆Ω is the width to half height of this mode) which can be considered poor in terms of signal guiding and filtering [24].…”
Section: Demultiplexer Based On Large Resonance Modessupporting
confidence: 53%
“…8(a 775, the transmission rate of defect modes is maximal through the second output line (Transmission 2). To give a real illustration of our analytical and numerical results, and for the sake of comparison with previous experimental and theoretical works [30] concerning the electromagnetic demultiplexing process, we choose the following demultiplexer parameters: for Channel…”
Section: Color Map Of Transmission Rates In Each Output Linementioning
confidence: 99%
“…The structure proposed in this work may have important applications for electronic transport in mesoscopic systems like filters and demultiplexers. The possibility to realize a Y-shaped demultiplexer [80] with one input line and two output lines; where each containing its own appropriate wire-ring resonator is in progress. Indeed, such as device would allow filtering a given energy in one line keeping the other line unaffected.…”
Section: Discussionmentioning
confidence: 99%
“…Due to their strong interest, Fano and EIT phenomena are not restricted to atomic systems and have been the subject of intense studies in classical systems including photonic waveguides [20][21][22], acoustic slender tubes [23,24], plasmonic nanostructures [25,26] and metasurfaces [27]. Recently, Fano and EIT resonances have been also studied in Y-shaped demultiplexers in various areas such as photonic circuits [28], acoustic slender tubes waveguides [29,30] and plasmonic nanostructures [31][32][33]. Also, it is worth noticing that photonic demultiplexers based on 1D and 2D photonic structures have been the subject of intense studies in the last two decades due to their great interest in global communication systems [2,28,[34][35][36][37].…”
Section: Introductionmentioning
confidence: 99%
“…Recently, Fano and EIT resonances have been also studied in Y-shaped demultiplexers in various areas such as photonic circuits [28], acoustic slender tubes waveguides [29,30] and plasmonic nanostructures [31][32][33]. Also, it is worth noticing that photonic demultiplexers based on 1D and 2D photonic structures have been the subject of intense studies in the last two decades due to their great interest in global communication systems [2,28,[34][35][36][37]. Different mechanisms are used for designing demultiplexers based on photonic crystals such as defect waveguides [38], coupled cavities [39][40][41][42], superprisms [43], coupling and cascading photonic crystal waveguides [44], photonic crystal ring resonators [45,46], Mach-Zehnder interferometers [47], and spiral resonators [48].…”
Section: Introductionmentioning
confidence: 99%