Ultra-high Q planar silicon microdisk resonators for chip-scale silicon photonics

Soltani, Mohammad; Yegnanarayanan, Siva; Adibi, Ali

doi:10.1364/oe.15.004694

Cited by 217 publications

(120 citation statements)

References 21 publications

(50 reference statements)

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“…For semiconductor microdisks the highest Q-factors can be achieved for "large" silicon cavities. Here, the Q ranges from 3 · 10 6 to 6 · 10 7 with disk radius of 20 − 60 µm Kippenberg et al, 2006;Soltani et al, 2007).…”

Section: B Optical Losses and Quality Factorsmentioning

confidence: 99%

Dielectric microcavities: Model systems for wave chaos and non-Hermitian physics

2015

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Section: B Optical Losses and Quality Factorsmentioning

confidence: 99%

Dielectric microcavities: Model systems for wave chaos and non-Hermitian physics

2015

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“…4d. Similar silicon micro-disk cavity with quality factor as high as 3 million has been reported in the literature 38 so it is possible to achieve even higher GF with a much lower power level. Although the operation speed of the device currently is limited by the relatively low mechanical frequency of the cantilevered signal waveguide, it is feasible to improve the mechanical frequency to the hundreds of megahertz range 39,40 , making it suited for radio-frequency (RF) photonics applications.…”

Section: Resultsmentioning

confidence: 68%

Multichannel cavity optomechanics for all-optical amplification of radio frequency signals

Chen

Noh

et al. 2012

Nat Commun

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optomechanical phenomena in photonic devices provide a new means of light-light interaction mediated by optical force actuated mechanical motion. In cavity optomechanics, this interaction can be enhanced significantly to achieve strong interaction between optical signals in chip-scale systems, enabling all-optical signal processing without resorting to electro-optical conversion or nonlinear materials. However, current implementation of cavity optomechanics achieves both excitation and detection only in a narrow band at the cavity resonance. This bandwidth limitation would hinder the prospect of integrating cavity optomechanical devices in broadband photonic systems. Here we demonstrate a new configuration of cavity optomechanics that includes two separate optical channels and allows broadband readout of optomechanical effects. The optomechanical interaction achieved in this device can induce strong but controllable nonlinear effects, which can completely dominate the device's intrinsic mechanical properties. utilizing the device's strong optomechanical interaction and its multichannel configuration, we further demonstrate all-optical, wavelengthmultiplexed amplification of radio-frequency signals.

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“…This design rule usually works well especially for low index-contrast (∆) optical waveguides (e.g., SiO 2 -on-Si buried optical waveguides). However, it becomes very different for small optical waveguides with very high ∆, e.g., submicron SOI waveguides, which have been used widely for ultra-compact CMOS-compatible PICs [45][46][47][48][49][50][51][52][53][54][55][56]. For high-∆ optical waveguides, mode conversion between the eigenmodes may occur in an adiabatic tapered structure due to the mode hybridization at some special waveguide widths [57][58][59][60][61][62].…”

Section: Tapered Optical Waveguidesmentioning

confidence: 99%

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

Dai¹,

Jian²,

He³

2013

PIER

113

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Abstract-Multimode spatial-division multiplexing (SDM) technology has attracted much attention for its potential to enhance the capacity of an optical-interconnect link with a single wavelength carrier. For a mode-multiplexed optical-interconnect link, the functional elements are quite different from the conventional ones as multiple modes are involved. In this paper we give a review and discussion on multimode photonic integrated devices for mode-multiplexed opticalinterconnects. Light propagation and mode conversion in tapered waveguides as well as bent waveguides are discussed first. Recent progress on mode converter-(de)multiplexers is then reviewed. The demands of some functional devices used for mode-multiplexed opticalinterconnects are also discussed. In particular, the fabrication tolerance is analyzed in detail for our hybrid demultiplexer, which enables mode-/polarization-division-(de)multiplexing simultaneously.

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Ultra-high Q planar silicon microdisk resonators for chip-scale silicon photonics

Cited by 217 publications

References 21 publications

Dielectric microcavities: Model systems for wave chaos and non-Hermitian physics

Dielectric microcavities: Model systems for wave chaos and non-Hermitian physics

Multichannel cavity optomechanics for all-optical amplification of radio frequency signals

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

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