Silicon Multimode Photonic Integrated Devices for on-Chip Mode-Division-Multiplexed Optical Interconnects

Dai, Daoxin; Jian, Wang; He, Sailing

doi:10.2528/pier13111003

Cited by 114 publications

(52 citation statements)

References 89 publications

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“…6(d). This indicates this type of adiabatic taper is robust for the applications of polarization rotation (as demonstrated in [23][24][25][26]), which might be useful for on-chip polarization-handling systems as well as mode-division-multiplexed optical interconnect systems [39]. For this kind of applications, one can further strengthen this kind of mode hybridization and mode conversion by e.g.…”

Section: Mode Hybridization and Conversion In Soi Nanowires With Anglmentioning

confidence: 86%

“…For an SOI nanowires with angled sidewalls, mode conversion between the TM 0 mode and higher-order TE modes might happens due to the mode hybridization in the regions around some specific waveguide widths. This mode conversion efficiency is possible to be very high (even close to 100%) when the taper is long enough to be adiabatic, which might be useful for some applications of multimode photonics [39,43]. For example, the TM 0 → TE 1 mode conversion can be utilized to realize polarization splitter-rotators [23][24][25][26].…”

Section: Discussionmentioning

confidence: 99%

“…For example, the TM 0 → TE 1 mode conversion can be utilized to realize polarization splitter-rotators [23][24][25][26]. Such a kind of mode conversion also possibly enables the data-exchange between these two mode channels for a mode-divison-multiplex optical interconnect link [39]. On the other hand, the mode conversion will become harmful due to the possible excess loss as well as crosstalk.…”

Section: Discussionmentioning

confidence: 99%

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Mode hybridization and conversion in silicon-on-insulator nanowires with angled sidewalls

Dai

Zhang

2015

Opt. Express

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The mode property and light propagation in a tapered silicon-on-insulator (SOI) nanowire with angled sidewalls is analyzed. Mode hybridization is observed and mode conversion between the TM fundamental mode and higher-order TE modes happens when light propagates in a waveguide taper which is used very often in the design of photonic integrated devices. This mode conversion ratio is possible to be very high (even close to 100%) when the taper is long enough to be adiabatic, which might be useful for some applications of multimode photonics. When the mode conversion is undesired to avoid any excess loss as well as crosstalk for photonic integrated circuits, one can depress the mode conversion by compensating the vertical asymmetry in the way of reducing the sidewall angle or introducing an optimal refractive index for the upper-cladding. It is also possible to eliminate the undesired mode conversion almost and improve the desired mode conversion greatly by introducing an abrupt junction connecting two sections with different widths to jump over the mode hybridization region.

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Section: Mode Hybridization and Conversion In Soi Nanowires With Anglmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Mode hybridization and conversion in silicon-on-insulator nanowires with angled sidewalls

Dai

Zhang

2015

Opt. Express

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“…[12][13][14][15] Various silicon-based on-chip (de)multiplexers have been demonstrated in the past years, [6] including arrayed-waveguide gratings for WDM, [17] and onchip polarization-handling devices for PDM, [18] as well as mode (de)multiplexers for MDM. [19][20][21] In particular, mode (de)multiplexer for MDM have been proposed by utilizing multimode interferometers, [22] asymmetric Y-junctions, [23,24] topology structures, [25] adiabatic couplers, [26,27] and asymmetric directional couplers (ADCs), [28][29][30] etc. Among them, ADC-based mode (de)multiplexers are popular [30] because of the structural simplicity, the scalability, and the flexibility to excite a desired high-order mode from a launched fundamental mode.…”

Section: Doi: 101002/lpor201700109mentioning

confidence: 99%

10‐Channel Mode (de)multiplexer with Dual Polarizations

Dai

Wang

et al. 2017

Laser & Photonics Reviews

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244

107

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A dual-polarization 10-channel mode (de)multiplexer is proposed and realized with cascaded dual-core adiabatic tapers on a silicon-on-insulator (SOI) platform. The mode demultiplexer has a 2.3 μm-wide multimode bus waveguide, which supports six mode-channels of TE polarization and four mode-channels of TM polarization. These ten mode-channels are (de)multiplexed with five cascaded dual-core adiabatic tapers based on SOI nanowires. The widths for these dual-cores are chosen optimally according to the dispersion curves of the dual-core SOI nanowire, so that the desired highest-order modes of TE-and TM-polarizations are extracted simultaneously. These two extracted mode-channels are coupled very efficiently to the fundamental modes of TE-and TM-polarizations (TE 0 and TM 0 ) in the narrow waveguide, respectively, which are then separated by using a polarization beam splitter based on bent directional couplers. A chip consisting of a pair of 10-channel mode (de)multiplexers is fabricated and then tested with data transmission of 30Gbps/channel. The measurement results show that all TM-and TE mode-channels have low crosstalks (-15ß-25 dB) and low excess losses (0.2ß1.8 dB) over a broad wavelength band of ß90 nm, which makes it WDM (wavelength-division-multiplexing)-compatible and thus suitable for high capacity on-chip optical interconnects.

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“…Therefore, we can make a power combiner of 100% efficiency if we let the two input fields have different wavelengths (i.e., the well-known wavelength-division-multiplexing technology, see, e.g., [4]), or have different polarizations (i.e., polarization multiplexing, see, e.g., [5]), or be of two modes orthogonal to each other (i.e., spatial mode multiplexing, see, e.g., [6]). Fig.…”

Section: Combination Through Different Channelsmentioning

confidence: 99%

On the Possibility of a Perfect Power Combiner

He¹,

Liu²

2017

PIER

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Abstract-By reductio ad absurdum, we show that a perfect power combiner of single-mode waveguides is impossible for incoherent input waves of the same frequency and same polarization as it is against the law of conservation of energy. The inevitable 3 dB loss of a three-port power combiner is explained physically. An incoherent power combiner of nearly 100% efficiency can be realized only if the two input fields have different wavelengths, have different polarizations, or are of orthogonal modes.

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Silicon Multimode Photonic Integrated Devices for on-Chip Mode-Division-Multiplexed Optical Interconnects

Cited by 114 publications

References 89 publications

Mode hybridization and conversion in silicon-on-insulator nanowires with angled sidewalls

Mode hybridization and conversion in silicon-on-insulator nanowires with angled sidewalls

10‐Channel Mode (de)multiplexer with Dual Polarizations

On the Possibility of a Perfect Power Combiner

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