2019
DOI: 10.1109/jlt.2019.2899372
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Ultra-Compact Terabit Plasmonic Modulator Array

Abstract: A new plasmonic transmitter solution offering 0.8 Tbit/s on an ultra-compact 90 µm × 5.5 µm footprint is introduced. It comprises a densely arranged four-channel plasmonic phase modulator array that directly interconnects an optical fiber array. Each plasmonic modulator features high-index grating couplers-for direct and efficient conversion from a fiber mode to a plasmonic slot mode and vice versa-and a plasmonic waveguide-for efficient high-speed modulation. The individual devices achieve data rates of 200 G… Show more

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Cited by 31 publications
(31 citation statements)
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“…By integrating the PPMs in a SiP Mach-Zehnder interferometer configuration, the phase modulation is translated into an amplitude or intensity modulation. These MZMs [36] can be used for radio-over-fiber applications and THz communication [29], [37], 200 Gbit/s intensity modulation [21] , 120 GBd IM with sub-1V pp driving electronics [20] as well as highly spatially parallelized modulator arrays for space-division multiplexing (SDM) and wavelength division multiplexing (WDM) applications [38], [39].…”
Section: B High-speed Plasmonic Modulatormentioning
confidence: 99%
“…By integrating the PPMs in a SiP Mach-Zehnder interferometer configuration, the phase modulation is translated into an amplitude or intensity modulation. These MZMs [36] can be used for radio-over-fiber applications and THz communication [29], [37], 200 Gbit/s intensity modulation [21] , 120 GBd IM with sub-1V pp driving electronics [20] as well as highly spatially parallelized modulator arrays for space-division multiplexing (SDM) and wavelength division multiplexing (WDM) applications [38], [39].…”
Section: B High-speed Plasmonic Modulatormentioning
confidence: 99%
“…In contrast, with device architectures based on a silicon slot waveguide 34 , 35 , 52 , 53 or a metal–insulator–metal plasmonic slot waveguide 23 28 , which are deployed in SOH and POH modulators, both optical and electrical fields could be tightly confined into nanoscopic dimensions with enhanced nonlinearities and concentrated electrical field, thereby reducing the π-voltage–length product in EO modulators, and shrinking the footprint to sub-millimetre 54 , 55 or micrometre 23 28 scales. The waveguide architecture of our device could be further optimized to realize a more compact footprint, which is of utmost importance in view of future ultra-dense high-speed parallelized interconnects to facilitate dense modulator arrays 56 , 57 for space-division multiplexing applications, and enable advanced complex modulations on a more compact footprint for coherent communications 45 , 58 . Besides, the synthesized side-chain EO polymer could be overlaid on the waveguide core as a cladding material to counterbalance the core’s TO coefficient, yielding athermal and high-speed MRRs with ultra-compact footprints 49 , 50 .…”
Section: Resultsmentioning
confidence: 99%
“…Using state-of-the-art silicon foundry coupling schemes would reduce the out-coupling losses by 10 dB 44 . Also, plasmonic losses of 3 dB for a 5 μm long device is possible 45 . Second, higher optical powers would be a solution to further increase the dynamical range.…”
Section: Methodsmentioning
confidence: 99%