Vertical optical ring resonators fully integrated with nanophotonic waveguides on silicon-on-insulator substrates

Madani, Abbas; Kleinert, Moritz; Stolarek, David; Zimmermann, Lars; Ma, Libo; Schmidt, Oliver G.

doi:10.1364/ol.40.003826

Cited by 36 publications

(36 citation statements)

References 35 publications

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“…Microtubular cavities are obtained by strain induced self-rolling of nanomembranes [17,18] which have previously received broad interest due to their unique properties including novel optical spin-orbit coupling phenomena [19], injection lasing [20], high opto-fluidic sensitivities [21], and compatibility with on-chip integration technologies [22,23]. This type of microcavity supports WGM resonances due to self-interference of light propagating along a circular ring trajectory defined by the tube cross section.…”

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confidence: 99%

Localized Surface Plasmons Selectively Coupled to Resonant Light in Tubular Microcavities

Yin

Böttner

et al. 2016

Phys. Rev. Lett.

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Vertical gold-nanogaps are created on microtubular cavities to explore the coupling between resonant light supported by the microcavities and surface plasmons localized at the nanogaps. Selective coupling of optical axial modes and localized surface plasmons critically depends on the exact location of the gold-nanogap on the microcavities which is conveniently achieved by rolling-up specially designed thin dielectric films into three dimensional microtube ring resonators. The coupling phenomenon is explained by a modified quasi-potential model based on perturbation theory. Our work reveals the coupling of surface plasmon resonances localized at the nanoscale to optical resonances confined in microtubular cavities at the microscale, implying a promising strategy for the investigation of light-matter interactions.

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confidence: 99%

Localized Surface Plasmons Selectively Coupled to Resonant Light in Tubular Microcavities

Yin

Böttner

et al. 2016

Phys. Rev. Lett.

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“…A partial list includes microrings [40,41], disks [12], knots/coils [42], bottles [43], droplets [44], goblets [45], rolled-up microcavities [46], bubbles [47], polystyrene microspheres [48,49], asymmetric cavities [50], cylinders [51], vertically coupled race track resonators [52], nearly spherical diamond resonators [53], crystalline CaF 2 cavities [54], and liquid-core optical ring resonators (LCORR) [55]. White-light WGM resonators have also been developed [56].…”

Section: Overview Of Different Types Whispering Gallery Mode Opticmentioning

confidence: 99%

“…( a ) Vertical optical ring resonators. Adapted from [46]; ( b ) Knot resonators; ( c ) Microbubble resonators. Reprinted from [47], with the permission of AIP Publishing; ( d ) Polystyrene microsphere resonators.…”

Section: Figurementioning

confidence: 99%

Label-Free Biological and Chemical Sensing Using Whispering Gallery Mode Optical Resonators: Past, Present, and Future

2017

Sensors

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Sensitive and rapid label-free biological and chemical sensors are needed for a wide variety of applications including early disease diagnosis and prognosis, the monitoring of food and water quality, as well as the detection of bacteria and viruses for public health concerns and chemical threat sensing. Whispering gallery mode optical resonator based sensing is a rapidly developing field due to the high sensitivity and speed of these devices as well as their label-free nature. Here, we describe the history of whispering gallery mode optical resonator sensors, the principles behind detection, the latest developments in the fields of biological and chemical sensing, current challenges toward widespread adoption of these devices, and an outlook for the future. In addition, we evaluate the performance capabilities of these sensors across three key parameters: sensitivity, selectivity, and speed.

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“…The rolling mechanism for the fabrication of the tubular shape of this structure facilitates the achievement of 3D light confinement in azimuthal, radial, and axial directions [9,10] . Furthermore, several experimental reports on the vertical coupling of this structure and other waveguides, both manually and monolithically, have been presented [11,12] . To the best of our knowledge, there has been no research conducted on designing passive SRM-based optoelectronic devices, particularly on an OADM, so far.…”

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confidence: 99%

Vertical integration of self-rolled-up microtube and silicon waveguides: a two-channel optical add–drop multiplexer

Sedaghat

Zarifkar

2017

中国光学快报

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A novel design of a two-channel optical add-drop multiplexer based on a self-rolled-up microtube (SRM) is presented. This design consists of an SRM that has a parabolic lobe-like pattern along the tube's axial direction, as well as straight silicon waveguides and a 180°waveguide bend. The vertical configuration of the SRM and waveguides is analyzed by the coupled mode theory for achieving the optimum gap. In the critical coupling regime, when the device serves as an optical demultiplexer, the minimum insertion loss is 1.94 dB, and the maximum channel crosstalk is −6.036 dB. Also, as an optical multiplexer, the maximum crosstalk becomes −11.9 dB.

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Vertical optical ring resonators fully integrated with nanophotonic waveguides on silicon-on-insulator substrates

Cited by 36 publications

References 35 publications

Localized Surface Plasmons Selectively Coupled to Resonant Light in Tubular Microcavities

Localized Surface Plasmons Selectively Coupled to Resonant Light in Tubular Microcavities

Label-Free Biological and Chemical Sensing Using Whispering Gallery Mode Optical Resonators: Past, Present, and Future

Vertical integration of self-rolled-up microtube and silicon waveguides: a two-channel optical add–drop multiplexer

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