REFERENCES
77
References
[1] A. Einstein, “Zur quantentheorie der strahlung,”
[2] D. ter Haar,
[3] N. Basov and A. Prokorov, “3-level gas oscillator,”
1954.
[4] A. Schwalow and C. Townes, “Infrared and optical masers,”
1958.
[5] T. Maiman, “Stimulated optical radiation in ruby,”
[6] Z. Alferov, “Nobel lecture: The double heterostructure concept and its applications
in physics, electronics, and technology,”
[7] H. Kroemer, “A proposed class of heterojunction injection lasers,”
p. 1782, 1963.
[8] University of Cambridge, “Introduction to semiconductors.”
doitpoms.ac.uk/tlplib/semiconductors/printall.php
Physik. Zeitschr. 18, p. 121, 1917.The old quantum theory, Pergamon Press, New York, 1967.Zh. Eksp. Teor. Fiz. 27, p. 431,Phys. Rev. 112, p. 1940,Nature 187, p. 493, 1960.Rev. Mod. Phys. 73, p. 767, 2001.Proc. IEEE 51,http://www., [cited at 2 April 2008].
University of Cambridge [Online]
[9] University of Cambridge, “Light-emitting diodes.”
lightemittingdiodes.org
[Online]
[10] G. Gri
Lett.
[11] H. Han, D. Forbes, and J. Coleman, “InGaAs-AlGaAs-GaAs strained-layer
quantum-well heterostructuresquare ring lasers,”
p. 1994, 1995.
[12] C. Ji, M. Leary, and J. Ballantyne, “Long-wavelength triangular ring laser,”
Technol. Lett.
[13] L. Bach, “Wavelength stabilized single-mode lasers by coupled micro-square resonators,”
.http://www., [cited at 2 April 2008]. University of Cambridge.ffel, “Synthesis of optical filters using ring resonator arrays,” Photon. Technol.12, p. 810, 2000.IEEE J. Quantum Electron. 31,Photon.9, p. 1469, 1997.
Photon. Technol. Lett.
[14] H. Cao and M. Osinski, “Large s-section-ring-cavity diode lasers: directional
switching, electrical diagnostics, and mode beating spectra,”
15, p. 377, 2003.Photon. Technol. Lett.
17
[15] M. Hill, “A fast low-power optical memory based on coupled micro-ring lasers,”
, p. 282, 2005.
Nature
432, p. 206, 2004.
REFERENCES
[16] A. Liao and S. Wang, “Semiconductor injection lasers with a circular resonator,”
78
Appl. Phys. Lett.
[17] Z. Wang, G. Verscha
“Integrated small-sized semiconductor micro-ring laser with novel retro-reflector
cavity,”
[18] M. Sorel, G. Giuliani, R. M. A. Scirè, S. Donati, and P. Laybourn, “Operating
regimes of GaAs-AlGaAs semiconductor ring lasers: experiment and model,”
36, p. 801, 1980.ffelt, Y. Shu, G. Mezosi, M. Sorel, J. Danckaert, and S. Yu,Photon. Technol. Lett. 20, p. 99, 2008.
IEEE J. Quantum Electron.
[19] T. Krauss, R. D. L. Rue, P. Laybourn, B. Vogele, and C. Stanley, “E
ring lasers made by a simple self-aligned fabrication process,”
Quantum Electron.
[20] G. Gri
InGaAsP ring laser fabricated using bi-level dry etching,”
p. 146, 2000.
[21] S. H. Strogatz,
[22] L. A. Coldren and S. Corzine,
New York, 1995.
[23] R. Lang and K. Kobayashi, “External optical feedback e
injection laser properties,”
[24] G. van Tartwijk, “Semiconductor lasers with optical injection and feedback,”
Semiclass. Opt.
[25] G.Verscha
integrated semiconductor micro-ring lasers with e
reflectors,” in
[26] M. Born and E. Wolf,
[27] P. Tassin, “A Contribution to Nonlinear Optics with Left-Handed Materials,” Master’s
thesis, Vrije Universiteit Brussel, Brussels, 2005.
[28] H. Haken and H. Sauermann, “Nonlinear interactions of laser modes,”
39, p. 1187, 2003.fficient semiconductorIEEE J.1, p. 757, 1995.ffel, J. Abeles, R. Menna, A. Braun, J. Connolly, and M. King, “Low thresholdPhoton. Technol. Lett. 12,Nonlinear Dynamics and Chaos, Perseus Books, Jackson (TN), 1994.Diode Lasers and Photonic Integrated Circuits, Wiley,ffects on semiconductorIEEE J. Quantum Electron. 16, p. 347, 1980.Quantum7, p. 87, 1995.ffelt, Z.Wang, Y. Shu, G. Mezosi, J. Danckaert, M. Sorel, and S. Yu, “Highspeedfficient off-axis parabolicSemiconductor Lasers and Laser Dynamics III, 6997, SPIE, 2008.Principles of Optics, Pergamon, Oxford, 1980.Z. Phys.
173
[29] W. Lamb Jr., “Theory of an optical maser,”
[30] M. Sargent III, M. Scully, and W. L. Jr.,
(Mass.), 1974.
[31] F. Arecchi, G. Lippi, G. Puccioni, and J. Tredicce, “Deterministic chaos in laser with
injected signal,”
, p. 261, 1963.Phys. Rev. 134, p. A1429, 1964.Laser physics, Addison-Wesley, ReadingOpt. Commun. 51, p. 308, 1984.
REFERENCES
[32] M. S. Miguel, Q. Feng, and J. Moloney, “Light-polarization dynamics in surfaceemitting
semiconductor lasers,”
[33] G. Morthier,
[34] G.Van der Sande, L. Gelens, P. Tassin, A. Scirè, and J. Danckaert, “Two-dimensional
phase-space analysis and bifurcation study of the dynamical behavior of a semiconductor
ring laser,”
[35] Wolfram Mathworld, “Routh-hurwitz theorem.”
com/Routh-HurwitzTheorem.html
[36] F. Gantmacher,
[37] I. S. Gradshteyn and I. Ryzhik,
Academic Press, San Diego (CA), 2000.
[38] G.Verscha
report,” 2008.
[39] D. Bimberg, M. Grundmann, and N. N. Ledentsov,
Wiley, New York, 1999.
[40] A. Markus, J. X. Chen, O. Gauthier-Lafaye, J.-G. Provost, C. Paranthoën, and
A. Fiore, “Impact if intraband relaxation on the performance of a quantum dot
laser,”
[41] H. Koskenvaara, J. Riikonen, J. Sormunen, M. Sopanen, and H. Lipsanen, “Carrier
dynamics in strain-induced InGaAsP
[42] S. Anantathanasarn, R. Nötzel, P. van Veldhoven, F. van Otten, T. Eijkemans,
and J. Wolter, “Stacking and polarization control of wavelength-tunable (1.55
region) InAs
[43] Y. Tanguy, J. Houlihan, G. Huyet, E. A. Viktorov, and P. Mandel, “Synchronization
and clustering in a multimode quantum dot laser,”
[44] S. Melnik, G. Huyet, and A. V.Uskov, “The linewidth enhancement factor
quantum dot semiconductor lasers,”
[45] E. A. Viktorov, P. Mandel, I. O’Driscoll, O. Carrol, G. Huyet, J. Houlihan, and
Y. Tanguy, “Low-frequency fluctuations in two-state quantum dot lasers,”
Lett.
79Phys. Rev. A 52, p. 1728, 1995.High speed photonic components, Ghent University, Ghent, 2007.J. Phys. B: At. Mol. Opt. Phys. 41, p. 8, 2008.http://mathworld.wolfram., [cited at 2 April 2008]. Wolfram Mathworld [Online].Applications of the Theory of Matrices, Wiley, New York, 1959.Tables of Integrals, Series, and Products, 6th ed.,ffelt, S. Beri, L. Gelens, G.Van der Sande, and J. Danckaert, “VUB activityQuantum Dot Heterostructures,IEEE J. Quantum Electron. 9, p. 1308, 2003./InP quantum dots,” Physica E 32, p. 179, 2006.μm/InGaAsP/InP (100) quantum dots,” Appl. Phys. Lett. 88, 2006.Phys. Rev. Lett. 96, 2006.
ofOpt. Expr. 14, p. 2950, 2006.Opt.31, p. 2302, 2006.