InP-based optical waveguide MEMS switches with evanescent coupling mechanism

Pruessner, Marcel W.; Amarnath, K.; Datta, M.; Kelly, Daniel P.; Kanakaraju, S.; Ho, P.‐T.; Ghodssi, Reza

doi:10.1109/jmems.2005.851848

Cited by 45 publications

(33 citation statements)

References 42 publications

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“…Our system is thus the fiber equivalent of chip-based optical MEMS switches based on two evanescently coupled waveguides as demonstrated recently for example in silicon [12] and InP [13]. Comb actuators are usually used for moving sub-micron sized guiding beams and waveguides on chips [14].…”

Section: Introductionmentioning

confidence: 99%

“…Comb actuators are usually used for moving sub-micron sized guiding beams and waveguides on chips [14]. However, other methods have been recently introduced, including electrostatic actuation by means of a voltage applied directly to the waveguides [13] or by placing them in a non-uniform electric field created by nearby electrodes [15]. We demonstrate that the latter method gives a direct way to control light propagation in the dual-core fiber, leading to NEMS-type functionality in the system.…”

Section: Introductionmentioning

confidence: 99%

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Design of dual-core optical fibers with NEMS functionality

Podoliak¹,

Loh²,

Horák³

2014

Opt. Express

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An optical fiber with nano-electromechanical functionality is presented. The fiber exhibits a suspended dual-core structure that allows for control of the optical properties via nanometer-range mechanical movements. We investigate electrostatic actuation achieved by applying a voltage to specially designed electrodes integrated in the cladding. Numerical and analytical calculations are preformed to optimize the fiber and electrode design. Based on this geometry an all-fiber optical switch is investigated; we find that optical switching of light between the two cores can be achieved in a 10 cm fiber with an operating voltage of 35 V.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design of dual-core optical fibers with NEMS functionality

Podoliak¹,

Loh²,

Horák³

2014

Opt. Express

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“…13,15 A coupler switch using InP waveguides was operated by applying electrostatic forces between the freestanding waveguides. 13 In the case of a parallel-electrode actuator, a coupler gap smaller than two-thirds of the initial gap is not consistently controllable due to force instability. Using an in-plane comb-drive actuator, stable low-voltage operation has been realized for silicon waveguides.…”

Section: Introductionmentioning

confidence: 99%

“…7 Due to the very low power consumption associated with capacitive operation, this technology suits the large-scale integration and reduced energy consumption requirements of telecommunication systems. [8][9][10][11][12][13][14][15][16] Among these waveguide circuits, coupler switches have attracted interest due to the use of non-contact low-loss mechanisms.13,15 A coupler switch using InP waveguides was operated by applying electrostatic forces between the freestanding waveguides. 13 In the case of a parallel-electrode actuator, a coupler gap smaller than two-thirds of the initial gap is not consistently controllable due to force instability.…”

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confidence: 99%

Single and multiple optical switches that use freestanding silicon nanowire waveguide couplers

Akihama

Hane

2012

Light Sci Appl

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Silicon photonic devices consisting of nanowire waveguides are a promising technology for on-chip integration in future optical telecommunication and interconnection systems based on silicon-large scale integration fabrication. However, the accommodation of variable optical components on a chip remains challenging due to the small size of microchips. In this study, we investigated the characteristics of a microelectromechanical silicon nanowire waveguide switch with a gap-variable coupler. Due to its capacitive operation, the proposed waveguide switch consumed negligible power relative to switches that use a thermo-optical effect and carrier injection. The proposed switch was characterized using analyses based on coupled-mode theory for rectangular waveguides, as well as a simulation using the finite difference time domain method. A 232 single switch with an improved configuration and a 236 multiple switch composed of the 232 switches was designed and fabricated by a combination of electron beam lithography, fast-atom beam etching and hydrofluoric acid vapor sacrificial etching. The properties of the switches were measured and evaluated at a wavelength of 1.55 mm. 1 The monolithic fabrication of silicon waveguides and silicon electronics is useful for future integration in opto-electronic systems. Due to the high refractive index of silicon (,3.5 at a wavelength of 1.5 mm), silicon waveguide circuits can be miniaturized to be several orders of magnitude smaller than silica waveguide circuits. Several types of circuits that employ submicron-scale silicon waveguides, such as waveguide splitters/couplers and micro-rings, 2-4 have been reported. In addition, a waveguide switch that uses a thermo-optical effect 5 and an ultra-fast silicon waveguide light modulator based on changes in the refractive index of silicon by carrier injection 6 have been reported. Recently, submicron-scale waveguide switches for optical path changes using the nano-mechanical motions of electrostatic actuators have been reported. 7 Due to the very low power consumption associated with capacitive operation, this technology suits the large-scale integration and reduced energy consumption requirements of telecommunication systems. [8][9][10][11][12][13][14][15][16] Among these waveguide circuits, coupler switches have attracted interest due to the use of non-contact low-loss mechanisms.13,15 A coupler switch using InP waveguides was operated by applying electrostatic forces between the freestanding waveguides. 13 In the case of a parallel-electrode actuator, a coupler gap smaller than two-thirds of the initial gap is not consistently controllable due to force instability. Using an in-plane comb-drive actuator, stable low-voltage operation has been realized for silicon waveguides.

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“…If the interaction length is sufficient, total and coherent energy transfer can be achieved; therefore this principle can be exploited in the design of optical directional couplers. 13 In Fig. 1͑a͒, the proposed sensing scheme is outlined.…”

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confidence: 99%

Detection of nanomechanical motion by evanescent light wave coupling

Vlaminck

Roels

Taillaert

et al. 2007

Applied Physics Letters

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The authors demonstrate a technique allowing sensitive nanomechanical motion detection based on the evanescent light wave coupling between two photonic nanowires. Any relative motion between the nanowires results in a change in light coupling, providing a means of registering motion. The in-plane vibrations of a 220 nmϫ 400 nmϫ 10 m nanomechanical resonator were recorded using this method. An analysis of the sensitivity reveals the potential of this integrated technique to provide fast and sensitive motion detection. © 2007 American Institute of Physics. ͓DOI: 10.1063/1.2746067͔ Nanoelectromechanical systems ͑NEMSs͒ have received great attention in recent years. Most research has focused on resonant devices for sensor applications. 1,2 Through scaling of the mechanical sensing element from the micron-to the nanoscale, researchers were able to improve the detection limits in force and mass sensing drastically. Devices sensitive enough to measure the magnetic moment of a single electron spin 3 or to perform zeptogram scale mass sensing 4 have resulted from efforts in scaling. A central problem in the development of even more sensitive mechanical sensors is the fast and high-precision detection of motion. In many cases, the performance of the sensor is restricted by the efficiency of the motion detection method employed, more so than by the inherent capabilities of the mechanical element. Much research has been devoted to solving this problem and a myriad of optical and electronic techniques has been developed. 5 Optical motion detection techniques have the inherent advantage that optical signals can be communicated with very large bandwidth. 6-8 Unfortunately, for conventional optical techniques, diffraction effects limit the attainable detection limits when the mechanical devices are scaled. It has been anticipated that these issues can be overcome by integration of mechanical sensors with nanophotonics and by exploiting optical near-field effects. 1,5 Recently, it was shown that motion of micron-scale devices can be monitored through changes in end-to-end alignment of optical waveguides. [9][10][11] In this letter, we propose an integrated and near-field optical motion detection technique that exploits near-field optical evanescent-wave coupling. We demonstrate that the technique works efficiently for nanoscale mechanical resonators, with greater sensitivity than conventional optical techniques.The approach offers potential for applications where robust and sensitive measurement of motion is required and applications requiring remote detection or detection of motion in harsh environments. The integration of the device with photonic circuitry reduces the complexity of addressing large arrays of devices.The detection of nanomechanical motion is achieved through the near-field coupling of light from a photonic waveguide to a mechanical resonator. The mechanical resonator acts as a photonic waveguide; when the evanescent tails of the guided modes of the resonator and waveguide overlap, photons tunnel from one wavegu...

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InP-based optical waveguide MEMS switches with evanescent coupling mechanism

Cited by 45 publications

References 42 publications

Design of dual-core optical fibers with NEMS functionality

Design of dual-core optical fibers with NEMS functionality

Single and multiple optical switches that use freestanding silicon nanowire waveguide couplers

Detection of nanomechanical motion by evanescent light wave coupling

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