Two-port polarization independent electro-optically tunable wavelength filter in lithium niobate

Ping, Yang

30 September 2004

Two-port polarization independent electro-optically wavelength tunable filters based on asymmetric Mach-Zehnder structure in LiNbO3 substrate have been developed for 1.55μm application. The operation principle is based on Mach-Zehnder interference and TE↔TM mode conversion. Fabrication parameters for channel waveguides, interferometers and mode converters have been optimized. 7μm wide single mode straight channel waveguides were produced by diffusing 1050-1100A thick Ti into LiNbO3 substrate. Insertion loss of 3.6dB was achieved for both TE and TM polarization. Mach-Zehnder interferometer performance was optimized by testing the Y-branch on samples cut in half length compared to complete device. Best results were obtained from samples that were produced by diffusion at 1025 degC for 11 hours of 1050A thick Ti film, and by diffusion at 1025 degC for 12 hours of 1090A thick Ti film. Metal electrodes were added to one arm of asymmetric Mach-Zehnder interferometers to evaluate electro-optic modulation. Modulation depth as high as 99.6% for TE mode and 98.9% for TM mode were obtained. TE↔TM mode conversion was demonstrated on straight channel waveguides with conversion efficiency greater than 96% utilizing 500 strain inducing SiO2 grating pads with 21μm spatial period. Two-port polarization independent electro-optically tunable wavelength filters were produced based on the optimized parameters described above. The -3dB bandwidth of the filter is 2.4nm. The nearest side lobe to the main peak is more than 13dB below the central lobe for both TE polarization and TM polarization. A thermal tuning rate of -0.765nm/degC is obtained. An electrical tuning range of 12.8nm and a tuning rate of 0.08nm/V were achieved.

filter

electro-optically

tunable

polarization independent

lithium niobate

Spectral slicing filters in titanium diffused lithium niobate (ti:linbo3)

Rabelo, Renato Cunha

15 May 2009

A tunable guided-wave optical filter that performs spectral slicing at the 1530nm wavelength regime in Ti:LiNbO3 was proposed and fabricated. It is aimed at minimizing crosstalk between channels in dense wavelength division multiplexing (DWDM) optical network applications. The design utilizes a sparse grating allowing the selection of equally spaced channels in the frequency domain. Between selected channels, equally spaced nulls are also produced. The sparse grating is formed by using N coupling regions with different lengths along the direction of propagation of light in the waveguide, generating N-1 equally spaced nulls between adjacent selected channels. The distance between the centers of adjacent coupling regions is kept constant. The filtering is based on codirectional polarization coupling between transverse electric (TE) and transverse magnetic (TM) orthogonal modes in a waveguide through an overlay of strain-induced index grating, via the strain-optic effect. Two types of devices were fabricated. In the first type, the sparse gratings were produced on straight channel waveguides. Selected channels emerge from the device in a polarization state orthogonal to the input and a polarizer is needed to observe the filtered light. For the second type, an asymmetric Mach-Zehnder interferometer configuration was used to eliminate the need of the polarizer at the output, and yields an output response that is polarization independent. Both types of devices were fabricated on x-cut y-propagating LiNbO3 substrates, with N = 6 strain-induced coupling regions. The single mode channel waveguides were formed by Ti diffusion. Electrode patterns centered about the optical waveguide were defined by liftoff. In the straight channel devices, insertion loss was less than 2.5 dB on a 43 mm sample. The 3-dB channel bandwidth of the selected channels is approximately 1.0 nm. Devices were tuned thermally as well as by voltage application to surface electrodes resulting in tuning rates of 1.0 nm/oC and 0.04148 nm/V, respectively. In the polarization independent device the insertion loss for the phase-matched wavelength was 5.3 dB on a 53 mm long chip. The 3-dB bandwidth was also ~1.0 nm and the thermal tuning rate 1.0 nm/oC. The experimental results are in good agreement with design theory.

Integrated Optics

Lithium Niobate

Optical Filter

Sparse Grating

Fabrication of Annealed Proton-Exchanged Waveguides for Vertical Integration

Webb, Jacob Douglas

2011 May 1900

There is a drive for improving the surface uniformity of optical waveguide devices in the photonics lab. This report focuses on the exploration of annealed proton exchange (APE) waveguide fabrication on lithium niobate crystal as a method of producing optical waveguides. These waveguides aim to have little variation in step height or surface roughness in the transition area from the waveguide location to that of the bulk crystal, providing a uniform surface amenable to vertical device integration. This is a substantial improvement over the titanium diffused waveguide process, which can have surface variations in excess of 100nm. It is anticipated that the smoother surface will enable light to couple more easily into photonic devices, such as ring resonators, as compared to the current Ti diffused waveguide process. This work explores the design and fabrication aspects of annealed proton exchange waveguides. A review of literature on modeling hydrogen diffusion into lithium niobate is presented, as well as computer models for simulating the bidimensional fractional hydrogen proton concentration distribution. This is used to determine the change in refractive index of the waveguide needed to simulate the mode propagation and profile in the device. Fabrication processes involved in proton exchange waveguide formation are outlined, and measurements for working devices are presented. Best case loss for current devices are 0.5 dB/cm. These samples exhibit smooth surfaces with only ±60A in variation of surface uniformity. Concluding remarks present ideas to further the work by lowering propagation losses, improving mode matching to single mode fiber, and improving the consistency of fabrication conditions.

optical

waveguide

proton

exchange

fabrication

lithium niobate

LiNbO3

APE

anneal

Guidage et filtrage des ondes dans les cristaux phononiques

Benchabane, Sarah

06 December 2006

Cette thèse, réalisée au sein du département de Physique et de Métrologie des Oscillateurs de l'institut FEMTO-ST sous la direction de Vincent Laude et d'Abdelkrim Khelif, s'inscrit dans le courant de recherche dédié depuis quelques années à l'étude de la propagation des ondes dans les matériaux à bandes interdites pour les ondes élastiques, ou cristaux phononiques.<br />La première partie de ces travaux a consisté à mettre expérimentalement en évidence l'existence de phénomènes de filtrage, guidage et couplage des ondes dans des structures périodiques de dimension millimétrique constituées de tiges d'acier dans de l'eau, opérant à une fréquence de l'ordre de la dizaine de kilohertz.<br />La seconde partie de cette thèse a été consacrée à la fabrication et à la caractérisation de cristaux phononiques à l'échelle de la dizaine de microns en niobate de lithium pour des applications aux ondes de surface à plus haute fréquence (quelques centaines de mégahertz). La caractérisation électrique comme optique des cristaux phononiques a permis de mettre en évidence l'existence d'une bande interdite complète pour les ondes de surface dans cette structure périodique. Des expériences similaires menées sur des structures en silicium ont encore confirmé ces résultats expérimentaux.<br />Enfin, la dernière partie de ces travaux a été dédiée à l'étude théorique des interactions acousto-optiques dans des matériaux présentant des bandes interdites à la fois photoniques et phononiques. Elle a permis de révéler l'importance du formalisme mathématique employé, dans cette configuration particulière où ondes optiques et élastiques sont fortement confinées.

Cristaux phoniques

acousto-optique

niobate de lithium

Modelocked waveguide lasers in lithium niobate /

Wessel, Rudolf.

January 2000

Thesis (doctoral)--Universität, Paderborn, 2000.

Two-port polarization independent electro-optically tunable wavelength filter in lithium niobate

Ping, Yang

30 September 2004

Two-port polarization independent electro-optically wavelength tunable filters based on asymmetric Mach-Zehnder structure in LiNbO3 substrate have been developed for 1.55μm application. The operation principle is based on Mach-Zehnder interference and TE↔TM mode conversion. Fabrication parameters for channel waveguides, interferometers and mode converters have been optimized. 7μm wide single mode straight channel waveguides were produced by diffusing 1050-1100A thick Ti into LiNbO3 substrate. Insertion loss of 3.6dB was achieved for both TE and TM polarization. Mach-Zehnder interferometer performance was optimized by testing the Y-branch on samples cut in half length compared to complete device. Best results were obtained from samples that were produced by diffusion at 1025 degC for 11 hours of 1050A thick Ti film, and by diffusion at 1025 degC for 12 hours of 1090A thick Ti film. Metal electrodes were added to one arm of asymmetric Mach-Zehnder interferometers to evaluate electro-optic modulation. Modulation depth as high as 99.6% for TE mode and 98.9% for TM mode were obtained. TE↔TM mode conversion was demonstrated on straight channel waveguides with conversion efficiency greater than 96% utilizing 500 strain inducing SiO2 grating pads with 21μm spatial period. Two-port polarization independent electro-optically tunable wavelength filters were produced based on the optimized parameters described above. The -3dB bandwidth of the filter is 2.4nm. The nearest side lobe to the main peak is more than 13dB below the central lobe for both TE polarization and TM polarization. A thermal tuning rate of -0.765nm/degC is obtained. An electrical tuning range of 12.8nm and a tuning rate of 0.08nm/V were achieved.

filter

electro-optically

tunable

polarization independent

lithium niobate

Implementation of AlGaN/GaN based high electron mobility transistor on ferroelectric materials for multifunctional optoelectronic-acoustic-electronic applications

Lee, Kyoung-Keun.

January 2009

Thesis (M. S.)--Electrical and Computer Engineering, Georgia Institute of Technology, 2009. / Committee Chair: William. Alan Doolittle; Committee Member: Jeffrey Nause; Committee Member: Linda S. Milor; Committee Member: Shyh-Chiang Shen; Committee Member: Stephen E. Ralph.

Electrooptic electric field sensor for dc and extra-low-frequency measurement

Bordovsky, Michael

January 1998

The thesis reports the results of the research carried out towards the development of an electrooptic sensor for DC and extra low frequency electric field measurement. Available cubic electrooptic crystals were compared from the sensor sensitivity point of view. A new figure of merit was used taking into account the attenuation of the electric field in the dielectric crystal and its shape. The effect of optical activity in 23 cubic crystals was analyzed using the concept of Poincare sphere. The cubic crystals were further characterised for the charge relaxation time constant to estimate their performance in DC field measurements. Crystals of Bismuth Germanate and Lithium Niobate were identified as suitable materials for the DC field sensor. The selected crystals were found suitable at extra-low-frequencies. DC field measurements, without the rotation of the crystal, were possible only with Lithium Niobate. However, its performance was influenced to a great extent by the effect of stimulated conductivity. The quarter-wave plate and the crystal of Lithium Niobate were identified as the main sources of temperature instability. A new method of temperature compensation of the quarter-wave plate is proposed. Due to the temperature instability of Lithium Niobate, mainly attributed to the pyroelectric effect and natural birefringence, it is difficult to use the sensor in practical applications. The performance of the sensor is significantly affected by the presence of an external space charge. The proposed method of its elimination using an artificial extension of the sensing element did not reduce the space charge effect adequately. The response of the sensor in a space charge environment was found to be linear and independent of the space charge density. This enabled measurements of static fields in a unipolar environment. The direct field measurements in bipolar environment suffered from a drift which is intolerable in practical measurements. The minimum detectable electric field of this sensor in the frequency range from 1 to 200Hz was 1V/m, with a signal to noise ratio equal to 0dB and a resolution of 1V/m. The static field measurements were limited to measurements of pulses with a duration of 200s, due to a long term drift of photodetectors. The minimum detectable level of DC electric field was 2.4kV/m.

621.381045

Études par spectroscopie Raman polarisée des effets photoélectrostrictifs dans LiNbO3 photoréfractif / Studies of photo-electrostrictives effects in photorefractive LiNbO3 by polarized Raman spectroscopy

Kokanyan, Ninel

30 January 2015

Le niobate de Lithium est un matériau optique utilisé dans de nombreuses applications en optoélectroniques grâce à ses propriétés électro-optiques, piézoélectriques et optiques non linéaire assez exceptionnelles. Parmi ces propriétés et applications, l’effet photoréfractif a engendré de nombreuses études. Cet effet dépend de la nature et de la concentration du dopant ; plus particulièrement, le dopage par des ions Fe est connu pour permettre d’augmenter l’efficacité photoréfractive. Il est donc important de connaitre et de maitriser la structure du matériau hôte lors du dopage Fe. L’objectif du travail de thèse consiste à étudier par spectres Raman les modifications générées par l’effet photoréfractif. Nos résultats montrent que la photorefractivité se manifeste par des effets différents : une déformation mécanique de la maille cristalline, provoquant un déplacement de certaines raies Raman ; la défocalisation du faisceau laser perturbant sa propagation dans le matériau, et ainsi des changements dans le spectre Raman ; des effets non linéaires de polarisation se manifestant par l’activation de raies Raman interdites / Lithium Niobate is an optical material used in many applications in optoelectronics through its electro-optical, piezoelectric and quite exceptional nonlinear optical properties. Among these properties and applications, the photorefractive effect has created numerous studies. This effect depends on the nature and the concentration of dopant; in particular by doping with Fe ions is known to increase the photorefractive efficiency. It is therefore important to know and to manage the structure of the material during Fe doping. The aim of the thesis is to study Raman spectra changes generated by the photorefractive effect. Our results show that the photorefractivity is manifested by different effects : a mechanical deformation of the crystal lattice, causing a displacement of some Raman lines ; the defocusing of the laser beam disrupting its propagation in the material, and thus changes in the Raman spectrum ; nonlinear effects of polarization manifested by activating of forbidden Raman lines

Niobate de lithium

Piézoélectriques

Optiques non linéaire

Photoréfractif

537.56

620.112 95

Femtosecond Laser Micromachining of Lithium Niobate

Driedger, Paul T.

02 1900

<p> Lithium niobate is an important photonic material that has potential applications in MEMS. Unfortunately, it is difficult to process using conventional methods. This thesis is an exploratory study to determine the viability of using a femtosecond laser as a fabrication tool for lithium niobate. Unexpectedly, a rich range of behaviour, likely arising from the complex material structure and composition, was discovered. Depending on the processing conditions, it was demonstrated that machining can either result in deep, high-aspect ratio grooves with minimal surrounding damage or dramatic modification of the lithium niobate to great depths with very little material removal.</p> <p> When machining grooves, increasing the effective number of pulses Neff (i.e. decreasing cutting speed) gave rapidly increasing ablation depths until a threshold was reached, after which the grooves were nearly filled with amorphous material. The depth of these amorphous channels rapidly saturates and becomes nearly independent of Neff. The ablation depth dependence on fluence showed gentle and strong ablation regimes. The amorphous channel depth depended almost linearly on fluence. Subsequent laser passes over amorphous channels eventually removed the amorphous material from the groove, indicating a dependence on the time between laser pulses. Crystal orientation was not a factor.</p> <p> The results are understood in terms of incubation and wave guiding. The first pulses ablate some material and incubate a channel of material below the surface. With further pulses, increasing incubation accelerates ablation. At the threshold Neff, the absorption coefficient has increased enough that the next pulse is able to melt a significant amount of material, which expands to fill the groove. It is suggested that, initially, the amorphous material is able to guide subsequent pulses to the bottom of the channel, resulting in a very slowly increasing depth with Neff. Subsequent passes cause ablation once again since compositional changes in the amorphous material have relaxed. Irradiated samples appear thermally reduced, which would create colour centres leading to increased absorption and thus incubation.</p> <p> Femtosecond lasers are indeed able to create MEMS structures. Multiple passes in the ablation regime yielded deep grooves, with laser polarization perpendicular to the groove giving the best results. Fabrication of micro-cantilevers and bridges was demonstrated.<p> / Thesis / Master of Applied Science (MASc)