Edwin Jan Klein - Universiteit Twente

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E. J. Klein, D. H. Geuzebroek, H. Kelderman and A. Driessen, “Wavelength selective switch using thermally tunable resonators,” In (Ed.), Proceedings 2004 Symposium LEOS Annual Meeting 2003 (pp. MM1), Tucson, Arizona, U.S.A., ISBN issn:1092- 8081. Conference proceedings E. J. Klein, G. Sengo, L. T. H. Hilderink, M. Hoekman and A. Driessen, “Reconfigurable λ-Router based on thermally tunable vertically coupled microring resonators in Si3N4/SiO2,” poster at the ePIXnet Winterschool 2007, 11-16 March, Pontresina, Switzerland, 2007. E. J. Klein, D. H. Geuzebroek, H. Kelderman, C. Bornholdt and A. Driessen, “40 Gbit/s Optical Add-Drop Multiplexer in Si3N4 based on Microring Resonators,” Poster at the Mesa+ Meeting 2005, University of Twente, Enschede, The Netherlands, 29 September 2005. E. J. Klein, D. H. Geuzebroek, H. Kelderman and A. Driessen, “Integrated Optical adddrop multiplexer using thermally tunable microring resonators,” In (Ed.), Proceedings 2004 Symposium LEOS/LEOS Benelux Chapter, University of Ghent, ISBN: 9076546061. M. Balakrishnan, E. J. Klein, M. Faccini, M. B. J. Diemeer, W. Verboom, A. Driessen, D. N. Reinhoudt, A. Leinse, “Fabrication of an electro-optic polymer microring resonator,” In (Ed.), Proceedings of 11th annual symposium of IEEE/LEOS Benelux, pp. 73-76, 2006, ISBN:90-6144-989-8. R. Dekker, E. J. Klein, J. Niehusmann, M. Först, F. Ondracek, J. Ctyroky, N. Usechak and A. Driessen, “Self Phase Modulation and Broadband Raman Gain in Silicon-on- Insulator Waveguides,” poster at the ePIXnet Winterschool 2006, 13-17 March, Pontresina, Switzerland, 2006. R. Dekker, E. J. Klein, J. Niehusmann, M. Forst, F. Ondracek, J. Ctyroky, N. Usechak and A. Driessen, “Self phase modulation and stimulated raman scattering due to high power femtosecond pulse propagation in silicon-on-insulator waveguides”, Poster in Proceedings of the Symposium IEEE LEOS Benelux, Mons, Belgium, 1-2 December 2005, Pp. 197-200, Editors: P. Mégret, M. Wuilpart, S. Bette, N. Staquet, ISBN: 2-9600226-4-5. R. Dekker, M. B. J. Diemeer, E. J. Klein, L. T. H. Hilderink, K. Wörhoff and A. Driessen, “Photo-Patternable Polymer Waveguides for microring Resonators,” Proceedings of the 31 st European Conference on Optical Communications (ECOC), Glasgow, Scotland, 25-29 September 2005, Vol. 2, Paper Tu 1.6.7, pp. 187-188, ISBN 0-86341-544-X. R. Dekker, E. J. Klein, A. Driessen, J. Niehusman, M. Forst, F. Ondracek and J. Ctyroky, “Femtosecond pulse propagation through nanophotonic structures,” Poster at the Mesa+ Meeting 2005, University of Twente, Enschede, the Netherlands, 29 September 2005. 216
R. Dekker, L.T.H.Hilderink, M.B.J. Diemeer, E.J. Klein, K. Wörhoff and A. Driessen, “Rare-earth-doped nanoparticles dispersed in photo-definable polymers for use in microring resonator devices,” LEOS Benelux Workshop, Eindhoven, May 20 th 2005. A. Driessen, D. H. Geuzebroek, H. J. W. M. Hoekstra, H. Kelderman, E. J. Klein, D. J. W. Klunder, C. G. H. Roeloffzen, F. S. Tan, E. Krioukov, C. Otto, H. Gersen, N. F. van Hulst and L. Kuipers, “Microresonators as building blocks for VLSI photonics,” In F. Michelotti, A. Driessen, M. Bertolotti (Eds.), Proceedings 39 th Course of the International School of Quantum Electronics “Microresonators as building blocks for VLSI photonics,” pp. 413-414, Melville, New York, USA: American Institute of Physics, 2004. A. Driessen and E.J. Klein, “Optical microring resonators as promising building blocks for VLSI photonics”, Invited talk, 3rd International Symposium on VLSI Photonics, 2006, Opera-Inha University, Inha, South Korea. A. Driessen and E.J. Klein, “Photonic integration technology of silicon oxynitride based microring devices”, Invited talk, WAPITI/PICMOS workshop, 7-12-2006, Halle, Germany. A. Driessen, D.H. Geuzebroek and E.J. Klein, “Optical network components based on microring resonators,” Invited talk, In (Ed.), Proceedings ICTON 2006, Nottingham, 2006, IEEE Catalog Number: 06EX1326, ISBN: 1-4244-0236-0, Library of Congress: 2006921097. A. Driessen, D.H. Geuzebroek and E.J. Klein, “High index contrast photonics components for optical data communication,” Invited talk, OFC 2006, Anaheim (Ca), paper OThE3. 9-3-2006. A. Driessen, R. Dekker, M. B. J. Diemeer, D. H. Geuzebroek, H. J. W. M. Hoekstra, E. J. Klein, A. Leinse, “Microresonators as promising building blocks for VLSI photonics,” Invited paper, Proceedings of SPIE, Conference on Integrated Optics: Theory and Applications, Warsaw, Poland, 31 August – 2 September 2005, Vol. 5956, Pp. 59560Q-1 – 59560Q-14, ISBN number: 0-8194-5963-1, ISSN: 0277-786X, Editors: P.V. Lambeck, C. Gorecki. Organized by SPIE Poland Chapter, SPIE Europe and Warsaw University of Technology, Poland. D. H. Geuzebroek, R. Dekker, E. J. Klein, C. Bornholdt, J. Niehusmann and A. Driessen, “Behavior of picosecond and femtosecond pulses in SiO2/Si3N4 microring resonator filters,” In (Ed.), Proceedings of the Symposium IEEE LEOS Benelux, Mons, Belgium, 1-2 December 2005, Pp. 51-54, Editors: P. Mégret, M. Wuilpart, S. Bette, N. Staquet, ISBN: 2-9600226-4-5. D. H. Geuzebroek, E. J. Klein, H. Kelderman, C. Bornholdt and A. Driessen, “40 Gbit/s Reconfigurable Add-Drop Multiplexer base don Microring Resonators,” In (Ed.), Proceedings of the 31 st European Conference on Optical Communications (ECOC), Glasgow, Scotland, 25-29 September 2005, Vol. 4, Invited Paper Tu 3.6.1, pp. 983-986, ISBN 0-86341-544-X. 217
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DENSELY INTEGRATED MICRORING- RESON
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DENSELY INTEGRATED MICRORING- RESON
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To my parents…
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esonators is limited by the spacing
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iv Samenvatting Dit proefschrift be
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schakelaar “aan” is, dan is de
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3.6.2 Overlap loss reduction.......
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Chapter 1 Introduction The devices
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1.2 Broadband to the home 3 Introdu
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1.3 Bringing Fiber to the Home 5 In
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Figure 1.5. The technological scope
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9 Introduction these basic paramete
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Chapter 2 2.1 Introduction Integrat
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Chapter 2 light Icav2 in the cavity
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Chapter 2 ∆ = ⎛ β r − β g
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Chapter 2 2.3.3 Combined model The
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Chapter 2 FC 4µ 1µ 2 ⋅ χr = 2
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Chapter 2 P Through /P In (dB) 0 -1
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Chapter 2 The figure shows that it
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Chapter 2 In − jϕr1 2 Figure 2.1
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Chapter 2 differences between the f
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Chapter 2 M = ⋅ FSR = N ⋅ FSR F
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Chapter 2 the heat will therefore f
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Chapter 2 index. Although this can
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Chapter 2 resonators for instance h
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Chapter 2 a rather complex MEMS bas
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Chapter 3 3.1 Introduction The most
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Chapter 3 3.2.1 Drop port on-resona
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Chapter 3 3.2.3 Filter bandwidth In
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Chapter 3 (resulting in a higher ba
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Chapter 3 Figure 3.11. Residual cha
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Chapter 3 3.3 Geometrical design ch
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Chapter 3 resonator and the port wa
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Chapter 3 Another important fact wh
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Chapter 3 The flowchart of the desi
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Chapter 3 While the resonator in th
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Chapter 3 3.6.1 Port waveguide and
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Chapter 3 overlap losses are only 0
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Chapter 3 3.7 Component design cons
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Chapter 3 By maximizing the power t
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Chapter 3 important, due to the fac
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Chapter 4 4.1 Introduction As was s
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Chapter 4 4.2.1 Transient response
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Chapter 4 Under the condition that
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Chapter 4 Figure 4.4. Screenshot of
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Chapter 4 The equations required to
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Chapter 4 using an approach based o
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Chapter 4 4.5.1 Architecture The Au
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Chapter 4 4.5.2 Simulation method A
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Chapter 4 Figure 4.9. A Primitive w
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Chapter 4 Listing 4.3. Pseudo code
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Chapter 4 Listing 4.4. Pseudo code
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Chapter 4 simulated output spectra
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Chapter 4 Figure 4.21. The reflecto
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Chapter 4 P Drop /P In (dB) 0 -10 -
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Chapter 4 Figure 4.27a. OADM with r
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Chapter 4 will propagate through th
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Chapter 4 As demonstrated by these
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Chapter 4 What is more interesting
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Chapter 4 method it does allow time
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Chapter 4 complex than the interact
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Chapter 5 5.1 Introduction The mate
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Chapter 5 wafer is used (step 1). T
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Chapter 5 range of 0.9 to 1.1 µm.
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Chapter 5 The process flow with the
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Chapter 5 5.3.3 Mask layout The big
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Chapter 5 5.4. Fabrication and mask
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Chapter 5 1. Definition of the vert
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Chapter 5 5.4.2 Fabrication The fab
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Chapter 5 Figure 5.21. Process flow
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Chapter 5 removed using lift-off of
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Chapter 6 6.1 Introduction About ha
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Chapter 6 In early, comparatively s
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Chapter 6 that the TEOS has a very
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Chapter 6 The most important aspect
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Chapter 6 6.2.3 Chromium heater des
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Chapter 6 Therefore, even if the si
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Chapter 6 Next, the heater was heat
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Chapter 6 6.3 Characterization of s
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Chapter 6 polarization maintaining
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Chapter 6 the resonators in this gr
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Chapter 6 Although the fitted coupl
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Chapter 6 a cladding thickness of 3
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Chapter 6 6.4 A wavelength selectiv
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Chapter 6 A possible explanation fo
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Chapter 7 Densely integrated device
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Densely integrated devices for WDM-
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Densely integrated devices for WDM-
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Page 183 and 184: 7.2.2 Spectral measurements Densely
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Page 209 and 210: Chapter 9 Discussion and Conclusion
Page 211 and 212: Appendix A. Mason’s rule Several
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Page 215 and 216: List of Acronyms ADSL - Asymmetric
Page 217 and 218: List of Symbols Q - Quality Factor
Page 219 and 220: Bibliography [1] Dan Schiller, “E
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Page 223 and 224: [66] B. E. Little, S. T. Chu, J. V.
Page 225 and 226: [97] H. Haeiwa, T. Naganawa and Y.
Page 227 and 228: [135] A. Driessen, D. H. Geuzebroek
Page 229 and 230: [165] T. Barwicz, M. R. Watts, M. A
Page 231: Publication List Patents (pending)
Page 235 and 236: Networks (BB Photonics),” Interna
Page 237 and 238: Dankwoord/Acknowledgements Zo, dit
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Edwin Jan Klein - Universiteit Twente

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