Presentation is loading. Please wait.

Presentation is loading. Please wait.

Jean-Marc Sabattié, Brian D. MacCraith, Karen Mongey,

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Jean-Marc Sabattié, Brian D. MacCraith, Karen Mongey,"— Presentation transcript:

1 Planar Optical Integrated Circuits Based on UV-Patternable Sol-Gel Technology
Jean-Marc Sabattié, Brian D. MacCraith, Karen Mongey, Jérôme Charmet, Kieran O’Dwyer, School of Physical Sciences, National Centre for Sensor Research, Dublin City University Mathias Pez, Francois Quentel,Thierry Dean THALES Research & Technology France

2 Plan Introduction Objectives Sol-Gel Technology Materials Preparation
UV-Patternable Sol-Gel Technology Waveguide Fabrication Process Parallel Optical Interconnects Assembly

3 Introduction Increase in communications traffic
 larger capacity networks Planar Lightwave Circuits (PLCs) as the future of optical communications: Passive devices: Parallel Optical Interconnects (POI), Splitters, Couplers... Active devices: Variable Optical Amplifiers...

4 Introduction Current technology: silica-on-silicon technology
expensive steps labour intensive refractive index range limitations Flame Hydrolysis Deposition / Chemical Vapour Deposition Undercladding Flame Hydrolysis Deposition and Consolidation Photolithography and Reactive Ion Etching Core overcladding waveguide Consolidation Si or SiO2 SiO2 SiO2/GeO2

5 Objectives Demonstration of the UV-patternable silica sol-gels technology for the manufacture of PLCs at room temperature at low cost Example: parallel optical interconnects transmitter chip (POI Tx)

6 Objectives: Tx module e- Parallel connector Silicon Substrate
Parallel waveguides Digital input hn e- Optical fibre ribbon Coupling optics wires Integrated circuit VCSEL array

7 Waveguide Structure Targets
8-waveguides array sub-module to be integrated into a transmitter chip Constraints: refractive indices are to match silica optical fibre parameters  D (refractive index core - refractive index cladding) = 0.02 Cladding Layer Silicon Substrate Guiding Layer

8 Zirconia used for refractive index tuning
Sol-Gel Technology Silica/zirconia are made via the sol-gel process from Alkoxide Precursors Si(OR)4 + 2 H2O SiO2 + ROH Zr(OR’)4 + 2 H2O ZrO2 + R’OH Zirconia used for refractive index tuning Catalyst

9 Refractive Index Tuning
Precursors for Cladding and Guiding Layers: Tetrathyl orthosilicate (TEOS) 3-(methoxysilyl)propyl methacrylate (MAPTMS) Zirconium Propoxide Irgacure 1800 (photoinitiator) Methacrylic acid (complexing agent for Zr propoxide)

10 Refractive Index Tuning
Dn = 0.01 for a 35 % concentration variation TEOS MAPTMS

11 Refractive Index Tuning
Dn = 0.01 for a 6 % concentration variation Zr propoxide

12 Refractive Index Tuning
Cladding and guiding materials preparation: Same amount of TEOS and MAPTMS in both materials to promote adhesion between layers to obtain materials with similar thermal expansion coefficients Refractive index difference (Dn) tuned by adjusting the Zirconium content

13 Hybrid UV-Patternable Sol-Gels
MAPTMS or 3-(methoxysilyl)propyl methacrylate Resulting structure with a non-hydrolysable group as obtained with such precursors

14 Hybrid UV-Patternable Sol-Gels
Aim: to create an organic network in parallel to the inorganic silica network by radical polymerisation non soluble in a wide range of solvents

15 Hybrid UV-Patternable Sol-Gels
Photoinitiator UV MAPTMS

16 Photolithography Standard Mask-Aligner

17 Waveguide Preparation Process
Spin-Coating cladding layer Spin-Coating cladding layer Thermal treatment Thermal treatment Spin-Coating guiding layer Dicing Waveguides UV-patterning Polishing facets Solvent wash Optical testing Thermal treatment

18 Refractive Index Tuning
UV-patterning step Parameters: Intensity, Duration, Wavelength Effect of the UV exposure on the refractive index of the guiding layer materials

19 Waveguide Array Fabrication
Rinsing step Picture of ridge waveguides 3D-Map of ridge waveguides Acquisition with Dektak V 200 Si surface profiler

20 Waveguide structures Characterisation of the waveguides
Ridge profile of a ridge waveguide Cross-section picture of a waveguide Acquisition with Dektak V 200 Si surface profiler Acquisition with optical microscope

21 Waveguide Array Fabrication Conclusions
Compromise between Refractive Index changes from Precursors UV-patterning Thermal treatments Hardness (for dicing, polishing) Temperature resistance (for electronics bonding)

22 Optical Testing End view of two waveguides, light injected at the other ends 250 mm 35.16 mm 32.34 mm Optical Loss = 0.79 dB/cm (measured at 840 nm by butt-coupling) Length of waveguides = ~1 cm

23 Tx module with connector
Waveguide array Silicon Signal out Signal in Silicon Fibre Ribbon Laser array driving electronics VCSEL array 850 nm Alignment Pin

24 Tx module with connector
Optical interface sub-module Fibre ribbon polished and metallized facet MT-ferrule VCSELs OE-component sub-assembly

25 overall transmission rate: 20 Gbit/s per device
POI Tx module testing Transmission tested at 2.5 Gbit/s/channel overall transmission rate: 20 Gbit/s per device

26 Conclusions Parallel Optical Interconnect demonstrator
UV-patternable sol-gel materials technology for PLC applications demonstrated Tunability of the materials for various applications (patterns, refractive index) Compatibility with electronics industry methods

27 Acknowledgements Brian D. MacCraith, Karen Mongey, Jérôme Charmet,
Kieran O’Dwyer NCSR / School of Physical Sciences, Dublin City University Ireland Mathias Pez, Francois Quentel, Thierry Dean THALES Research & Technology France, Domaine de Corbeville, France European Commission Brite-Euram Programme (Project number: BRPR-G ).

28 Thank you for your attention

Download ppt "Jean-Marc Sabattié, Brian D. MacCraith, Karen Mongey,"

Similar presentations

Flex Circuit Design for CCD Application ECEN 5004 Jon Mah.

Flex Circuit Design for CCD Application ECEN 5004 Jon Mah.
AVANEX Livingston, Starlow Park, Livingston, EH54 8SF

AVANEX Livingston, Starlow Park, Livingston, EH54 8SF
All-Silicon Active and Passive Guided-Wave Components

All-Silicon Active and Passive Guided-Wave Components
Optomechanical cantilever device for displacement sensing and variable attenuator 1 Peter A Cooper, Christopher Holmes Lewis G. Carpenter, Paolo L. Mennea,

Optomechanical cantilever device for displacement sensing and variable attenuator 1 Peter A Cooper, Christopher Holmes Lewis G. Carpenter, Paolo L. Mennea,
INTEGRATED CIRCUITS Dr. Esam Yosry Lec. #6.

INTEGRATED CIRCUITS Dr. Esam Yosry Lec. #6.
Valter Reedo 1,2, Martin Järvekülg 1,2, A. Lukner 1, K. Keevend 1, A. Lõhmus 1, U. Mäeorg 2 1 Institute of Physics, University of Tartu, Riia 142, EE-51014.

Valter Reedo 1,2, Martin Järvekülg 1,2, A. Lukner 1, K. Keevend 1, A. Lõhmus 1, U. Mäeorg 2 1 Institute of Physics, University of Tartu, Riia 142, EE
Industrial Affiliates Workshop, March 2004 Planar Ion-Exchanged Glass Waveguide Devices Seppo Honkanen, Brian West and Sanna Yliniemi Optical Sciences.

Industrial Affiliates Workshop, March 2004 Planar Ion-Exchanged Glass Waveguide Devices Seppo Honkanen, Brian West and Sanna Yliniemi Optical Sciences.
CMOS Compatible Integrated Dielectric Optical Waveguide Coupler and Fabrication Jeong-Min Lee High-Speed.

CMOS Compatible Integrated Dielectric Optical Waveguide Coupler and Fabrication Jeong-Min Lee High-Speed.
EE 230: Optical Fiber Communication Lecture 15 From the movie Warriors of the Net WDM Components.

EE 230: Optical Fiber Communication Lecture 15 From the movie Warriors of the Net WDM Components.
Tutorial on optical fibres F. Reynaud IRCOM Limoges Équipe optique F. Reynaud IRCOM Limoges Équipe optique Cargèse sept 2002.

Tutorial on optical fibres F. Reynaud IRCOM Limoges Équipe optique F. Reynaud IRCOM Limoges Équipe optique Cargèse sept 2002.
Radius of Curvature: 900 micron Fig. 1 a.) Snell’s Law b.) Total Internal Reflection a. b. Modeling & Fabrication of Ridge Waveguides and their Comparison.

Radius of Curvature: 900 micron Fig. 1 a.) Snell’s Law b.) Total Internal Reflection a. b. Modeling & Fabrication of Ridge Waveguides and their Comparison.
Optical Chemical Sensor Systems based on Photosensitive Hybrid Sol-Gel Glass B.D. MacCraith, S. Aubonnet, H. Barry, C. von Bültzingslöwen, J.-M. Sabattié,

Optical Chemical Sensor Systems based on Photosensitive Hybrid Sol-Gel Glass B.D. MacCraith, S. Aubonnet, H. Barry, C. von Bültzingslöwen, J.-M. Sabattié,
IMEC - INTEC Department of Information Technology WAVEGUIDES IN BOARDS BASED ON ORMOCER  s

IMEC - INTEC Department of Information Technology WAVEGUIDES IN BOARDS BASED ON ORMOCER  s
Sample Devices for NAIL Thermal Imaging and Nanowire Projects Design and Fabrication Mead Mišić Selim Ünlü.

Sample Devices for NAIL Thermal Imaging and Nanowire Projects Design and Fabrication Mead Mišić Selim Ünlü.
Fiber Optic Light Sources

Fiber Optic Light Sources
ECE 424 – Introduction to VLSI Design Emre Yengel Department of Electrical and Communication Engineering Fall 2012.

ECE 424 – Introduction to VLSI Design Emre Yengel Department of Electrical and Communication Engineering Fall 2012.
Monireh Moayedi Pour Fard Photonics system group McGill University July 2012.

Monireh Moayedi Pour Fard Photonics system group McGill University July 2012.
Photonic Devices - Couplers Optical fibre couplers A basic photonic device used to split or combine light to or from different fibres. A building block.

Photonic Devices - Couplers Optical fibre couplers A basic photonic device used to split or combine light to or from different fibres. A building block.
Fundamental of Fiber Optics. Optical Fiber Total Internal Reflection.

Fundamental of Fiber Optics. Optical Fiber Total Internal Reflection.
Array Waveguide Gratings (AWGs). Optical fiber is a popular carrier of long distance communications due to its potential speed, flexibility and reliability.

Array Waveguide Gratings (AWGs). Optical fiber is a popular carrier of long distance communications due to its potential speed, flexibility and reliability.

Similar presentations

Ads by Google