ZnSe/ZnS Quantum-Dot Semiconductor Optical Amplifiers

Similar documents
External (differential) quantum efficiency Number of additional photons emitted / number of additional electrons injected

A STUDY OF DYNAMIC CHARACTERIZATIONS OF GaAs/ALGaAs SELF-ASSEMBLED QUANTUM DOT LASERS

Saturation and noise properties of quantum-dot optical amplifiers

Laser Basics. What happens when light (or photon) interact with a matter? Assume photon energy is compatible with energy transition levels.

Microcavity Length Role On The Characteristic Temperature And The Properties Of Quantum Dot Laser

(b) Spontaneous emission. Absorption, spontaneous (random photon) emission and stimulated emission.

Optoelectronics ELEC-E3210

THE DEVELOPMENT OF SIMULATION MODEL OF CARRIER INJECTION IN QUANTUM DOT LASER SYSTEM

Signal regeneration - optical amplifiers

Paper Review. Special Topics in Optical Engineering II (15/1) Minkyu Kim. IEEE Journal of Quantum Electronics, Feb 1985

EE 472 Solutions to some chapter 4 problems

Chapter 2 Optical Transitions

Assignment 6. Solution: Assumptions - Momentum is conserved, light holes are ignored. Diagram: a) Using Eq a Verdeyen,

Photonic Devices. Light absorption and emission. Transitions between discrete states

Quantum Dot Lasers. Jose Mayen ECE 355

FIBER OPTICS. Prof. R.K. Shevgaonkar. Department of Electrical Engineering. Indian Institute of Technology, Bombay. Lecture: 17.

Stimulated Emission Devices: LASERS

Title: Ultrafast photocurrent measurement of the escape time of electrons and holes from

ANALYSIS OF AN INJECTION-LOCKED BISTABLE SEMICONDUCTOR LASER WITH THE FREQUENCY CHIRPING

Chapter 5. Semiconductor Laser

Course overview. Me: Dr Luke Wilson. The course: Physics and applications of semiconductors. Office: E17 open door policy

Noise in voltage-biased scaled semiconductor laser diodes

LASER. Light Amplification by Stimulated Emission of Radiation

6. Light emitting devices

Stimulated Emission. Electrons can absorb photons from medium. Accelerated electrons emit light to return their ground state

Luminescence Process

Principles of Lasers. Cheng Wang. Phone: Office: SEM 318

THREE-dimensional electronic confinement in semiconductor

interband transitions in semiconductors M. Fox, Optical Properties of Solids, Oxford Master Series in Condensed Matter Physics

Pressure and Temperature Dependence of Threshold Current in Semiconductor Lasers Based on InGaAs/GaAs Quantum-Well Systems

Laser Physics OXFORD UNIVERSITY PRESS SIMON HOOKER COLIN WEBB. and. Department of Physics, University of Oxford

Distributed feedback semiconductor lasers

Thermal performance investigation of DQW GaInNAs laser diodes

MTLE-6120: Advanced Electronic Properties of Materials. Semiconductor p-n junction diodes. Reading: Kasap ,

Surface Plasmon Amplification by Stimulated Emission of Radiation. By: Jonathan Massey-Allard Graham Zell Justin Lau

Introduction to Sources: Radiative Processes and Population Inversion in Atoms, Molecules, and Semiconductors Atoms and Molecules

Introduction to Optoelectronic Device Simulation by Joachim Piprek

Emission Spectra of the typical DH laser

Chemistry Instrumental Analysis Lecture 5. Chem 4631

Laser Diodes. Revised: 3/14/14 14: , Henry Zmuda Set 6a Laser Diodes 1

Impact of the carrier relaxation paths on two-state operation in quantum dot lasers

Near-Threshold Relaxation Dynamics of a Quantum Dot Laser

Photonics applications II. Ion-doped ChGs

Size-Dependent Biexciton Quantum Yields and Carrier Dynamics of Quasi-

Intraband emission of GaN quantum dots at λ =1.5 μm via resonant Raman scattering

Chapter-4 Stimulated emission devices LASERS

Microscopic Modelling of the Optical Properties of Quantum-Well Semiconductor Lasers

Pulsed Lasers Revised: 2/12/14 15: , Henry Zmuda Set 5a Pulsed Lasers

ISSN Review. Progress to a Gallium-Arsenide Deep-Center Laser

Excess carriers: extra carriers of values that exist at thermal equilibrium

Metal Vapour Lasers Use vapoured metal as a gain medium Developed by W. Silfvast (1966) Two types: Ionized Metal vapour (He-Cd) Neutral Metal vapour

- Outline. Chapter 4 Optical Source. 4.1 Semiconductor physics

1 Semiconductor Quantum Dots for Ultrafast Optoelectronics

Saturation Absorption Spectroscopy of Rubidium Atom

What Makes a Laser Light Amplification by Stimulated Emission of Radiation Main Requirements of the Laser Laser Gain Medium (provides the light

2. THE RATE EQUATION MODEL 2.1 Laser Rate Equations The laser rate equations can be stated as follows. [23] dn dt

Diode Lasers and Photonic Integrated Circuits

S. Blair February 15,

MODAL GAIN AND CURRENT DENSITY RELATIONSHIP FOR PbSe/PbSrSe QUANTUM WELL NORMAL AND OBLIQUE DEGENERATE VALLEYS

Q. Shen 1,2) and T. Toyoda 1,2)

1. Transition dipole moment

Resonantly Excited Time-Resolved Photoluminescence Study of Self-Organized InGaAs/GaAs Quantum Dots

SUPPLEMENTARY INFORMATION

LASERS. Amplifiers: Broad-band communications (avoid down-conversion)

Nanophotonic Waveguides by Self-Assembled Quantum Dots

Phys 2310 Fri. Dec. 12, 2014 Today s Topics. Begin Chapter 13: Lasers Reading for Next Time

Summary lecture IX. The electron-light Hamilton operator reads in second quantization

Solar Cell Materials and Device Characterization

Photonics and Optical Communication

EECE 4646 Optics for Engineers. Lecture 17

Influence of Plasmonic Array Geometry on Energy Transfer from a. Quantum Well to a Quantum Dot Layer

Internal Efficiency of Semiconductor Lasers With a Quantum-Confined Active Region

smal band gap Saturday, April 9, 2011

QUANTUM-DOT (QD) devices have attracted great attention

Broadband Quantum-Dot/Dash Lasers

Theory for strongly coupled quantum dot cavity quantum electrodynamics

MODELING THE FUNDAMENTAL LIMIT ON CONVERSION EFFICIENCY OF QD SOLAR CELLS

Fluorescence Spectroscopy

Characteristics of a Designed 1550 nm AlGaInAs/InP MQW VCSEL

Multiple Exciton Generation in Quantum Dots. James Rogers Materials 265 Professor Ram Seshadri

Time-Resolved Electronic Relaxation Processes In Self-Organized Quantum Dots. Final Report

Semiconductor device structures are traditionally divided into homojunction devices

Optical and Photonic Glasses. Lecture 31. Rare Earth Doped Glasses I. Professor Rui Almeida

Studies of the Spin Dynamics of Charge Carriers in Semiconductors and their Interfaces. S. K. Singh, T. V. Shahbazyan, I. E. Perakis and N. H.

School of Electrical and Computer Engineering, Cornell University. ECE 5330: Semiconductor Optoelectronics. Fall 2014

Photonic Crystal Nanocavities for Efficient Light Confinement and Emission

Other Devices from p-n junctions

Light emission from strained germanium

Recombination: Depletion. Auger, and Tunnelling

B 2 P 2, which implies that g B should be

Laser Types Two main types depending on time operation Continuous Wave (CW) Pulsed operation Pulsed is easier, CW more useful

Entangled Photon Generation via Biexciton in a Thin Film

Semiconductor Lasers II

Quantum Dot Lasers. Andrea Fiore. Ecole Polytechnique Fédérale de Lausanne

Contents Part I Concepts 1 The History of Heterostructure Lasers 2 Stress-Engineered Quantum Dots: Nature s Way

LASER. Light Amplification by Stimulated Emission of Radiation

Cathodoluminescence of Rare Earth Ions in Semiconductors and Insulators

Optical Properties of Semiconductors. Prof.P. Ravindran, Department of Physics, Central University of Tamil Nadu, India

Supporting Information. Femtosecond Time-Resolved Transient Absorption. Passivation Effect of PbI 2

Semiconductor Optical Amplifiers

Transcription:

Optics and Photonics Journal, 011, 1, 65-69 doi:10.436/opj.011.1010 Published Onle June 011 (http://.scirp.org/journal/opj/) ZnSe/ZnS Quantum-Dot Semiconductor Optical Amplifiers Abstract K. H. Al-Mossawi Scholarships & Cultural Affairs, Mistry of Higher Education & Scientific Research, Iraq E-mail: kadumalmosawi@yahoo.com. Received April 5, 011; revised May 7, 011; accepted May 17, 011 ZnSe quantum dot (QD) semiconductor optical amplifier (SOA) is studied theoretically usg net ga for lear Absorption coefficient and lear emission and these results are used to calculate noise figure and small-signal ga. Keywords: Lear Absorption Coefficient, Lear Emission Coefficient, Rate Equations (Res), Noise Figure 1. Introduction Quantum dot photonic materials have attracted much attention recent years as they have the potential to deliver the stability and coherence of atomic sources with a compact and efficient semiconductor device. characteristics such as reduced sensitivity to optical feedback makes such materials attractive as laser sources. In addition, suppression of pattern effects QD semiconductor optical amplifiers (SOAs) shown to be promises for high speed application. The understandg of the high speed carrier dynamics of these materials is crucial for their optimization and exploitation. To address this issue, time resolved spectroscopy has been used to vestigate the fundamental carrier decay time scales of SOA structures and determe their suitability for high-speed applications. Such pump-probe studies are usually performed usg pulse width of a few hundred femtoseconds to picoseconds order to sufficiently resolve the relaxation dynamics of high-speed devices. [1] Quantum dot (QD) semiconductor optical amplifiers (SOAs) demonstrate best features when compared with other SOAs based on bulk or quantum well materials. As a result, QD SOAs are very promisg for applications high-speed optical communications. One of the most important features of QD materials results these best performances is the discrete structure of their energy levels []. In this work, ZnSe/ZnS QD-SOAs are studied. First, energy levels are calculated usg quantum box model where the dot is assumed the form a cube with quantum dot size is 10 10 10 nm 3. net ga is then calculated by usg lear Absorption coefficient and lear emission coefficient components the QD.. Ga of QDs Ga and threshold current models are calculated with quasi-fermi levels energies E f c and E fv, which are directly controlled by the dopg concentration or jected current. Given that w x, w y and w z are the lengths each dimension of a quantum box, see Figure 1, and E cnml and E vnml are allowed quantized electron and hole energies, respectively, the correspondg carrier densities, n and p(~n) may be expressed as [3] n p fc Ecnml (1) nml nml Ecnml Ef c 1 exp kt 1 fvevnml () nml nml Ef E v cnml 1 exp kt w z w x barrier Figure 1. Diagram of dot/barrier quantum box. w y dot Copyright 011 SciRes.

66 K. H. AL-MOSSAWI ET AL. Where f c and f v are the correspondg Fermi functions for electrons the conduction and valence bands. The factor of two takes to account the electron sp. The summation is over all the confed energy states, which depends on the QD material and the dot/barrier valence and conduction band offsets (ΔE c and ΔE v ) that enable electron and hole confement. Solvg known E f c and E fv are ed for directly and applied to fd the lear absorption coefficient α(w) and lear emission coefficient e(w) components the QD [3] h g fv E11 fc E w o aw R de (3) nr o nml Eg h E hw h g fc E1 fv E1 w o ew R de nr o nml Eg h E hw Where R is the dipole moment, n r is the refractive dex and g is the density of states for the QD, given by [3] g E Ecnml Eg (4) (5) Where τ the traband relaxation time. Equations (3) and (4) signify the rates of absorption and emission per unit length with E 1 and E representg the hole energy level the valence band and the electron energy level the conduction band, respectively. The net ga of the system is then [3] Gwew aw (6) To determe the optimal operatg region for an amplifier system, the ga coefficient, expressed as [3] Gw ga coefficient (7) P 3. QD-SOA Based on the rate equations used [4] for the wettg layer (WL) carrier density N w, occupation probabilities for ground and exited states (f and h), respectively one can write. N w 1 w J N h Nwh Nw (8) t ql w w w wr 1 N L h 1 1 h N L h f h f h t N N w w w w Q w Q w 1 1 (9) 1 f h f 1h gl (10) f f p c f 1Sav t 1 1 1 R NQ s Where J is the current density, q is the electron charge, L w is the effective thickness of the active layer, τ w is the carrier relaxation time from the two-dimensional WL to the ES, τ w is the carrier escape time from the ES to the WL, τ wr is the spontaneous radiative lifetime WL, τ 1R is the spontaneous radiative lifetime the QDs, τ 1 is the carrier relaxation time from ES to GS, τ 1 is the carrier relaxation time from the GS to the ES, N Q is the surface density of QDs, ε s is the dielectric constant of the QD material and Г is the optical confement factor. g p is the peak material ga. Accordg to Pauli's exclusion prciple, the occupation probability the quantum-dot ground state relates to the carrier density N the QD by f = N/(N Q /w x ) [5] where w x is the size of the QD. The average signal photon density S av is given by [6] S av G Rf RbG Pn g (11) RRG RRG hwplwdlg pc 11 1 1 f b 4 f b s Where P is the put signal power, n g is the group refractive dex, ћ is the normalized Plank s constant, w p is the peak frequency, D is the width of the active layer, L is the cavity length, c is the free space light speed. Note that the Fibry-Perot amplifier ga G is given by [7] G 1 1 R R G f b S 1 f b s 4 f b ss RRG RRG (1) R f is the front mirror reflectivity, R b the back mirror reflectivity. Φ is the phase angle while G S is the sgle-pass ga of the structure, given by [7] Gs exp gpat L (13) Note that α t is the loss coefficient. The carrier dynamics described by the rate Equations are related only to electrons the conduction band while hole dynamics can be neglected due to their larger effective mass [4]. In addition, typical values of the material parameters Table 1 [5] for ZnSe/ZnS system where (E g =.8 ev, m e = 0.17 m o and m v = 0.60 m o ) for ZnSe and (E g = 3.68 ev, m e = 0.39 m o and m v = 0.49 m o ) for ZnS. Rate equations model are solved at steady state case usg the expression of the average signal photon density S av, Equation (11). The noise added to the signal durg the amplification process is a fundamental property for every kd of amplifiers. The noise characteristics of an amplifier are quantified by a parameter called noise figure, when the shot noise part is taken to account, the amplifier noise figure can be written as [7]. Copyright 011 SciRes.

K. H. AL-MOSSAWI ET AL. 67 Table 1. Parameters used the Calculations [5]. Parameter Value Unit L 00 μm L w 0. μm D 10 μm N Q 5 10 10 cm - τ w 3 ps τ w 1 ns τ 1 1. ps τ 1 0.16 ps τ 1R 0.4 ns τ wr 1 ns Φ 0 R f = R b 10 4 α t 3 1/cm Γ 0.006 L b 0 nm L c 75 nm P 1 μw F n G1 / G 1/ G (14) n sp The the spontaneous emission factor n sp is given by [8] n sp ew at G w (15) thus one can use this property to work with the same structure at higher ga by choosg the subbands that occur between them. Also, one can refers to the somewhat crease between the ground and excited peaks with raband relaxation time. Rate equations are then solved at steady state, usg the parameters listed Table 1, the QD-SOA characteristics are examed. Small-signal ga spectrum of this QD-SOA is shown Figure 6. These ga values are comparable to that obtaed by Ben-Azra [9]. Note that it is obtaed here at a lower current value. So, this is a good modification. The effect of QD layer is also examed where the ga creases with QD layers as shown Figure 7. Figure 8 shows the output power calculated as a function of carrier density with put power is taken as a parameter. Includg the shot noise part, the noise figure spectrum is shown Figure 9, while the noise figure curve at different carrier densities is shown Figure 10 from the last two figures one can refers to the lower noise accompanied with this amplifier while the last three figures shows the properties of ZnSe/ZnS QD-SOA which is a good results to use it applications. 4. Results and Discussion Usg quantum box model we calculate QD energy levels for conduction and valence bands and then it is used to calculate lear absorption coefficient, lear emission coefficient and net ga. The barrier layer thickness is 0 nm while the thickness of the clad layer is 75 nm, see Figure. All calculations are done at τ = 0.1 ps [3] and carrier density 10 4 m 3. Also we calculate the small signal ga for structures conta one and six layers. Ga coefficients are calculated usg Equation (7) for several values of put power. Figure 3 shows a comparison between the lear absorption and emission coefficients where a multi-peaks appear for ground and excited state transitions. One can refers to the higher emission value compared to that of absorption which results from lower transparency value for this structure. The net ga is shown Figure 4, where a double peak can also be seen. This is very important some applications. For example, this can be used long haul optical transmission. The reason for this double emission is reasoned to fite ground state relaxation time, which brgs ground state emission to a constant value after the excited state threshold [10]. Figure 5 shows the effect of traband relaxation time τ where a higher ga is obtaed at longer traband time. Ga of the highest peak creases by ~ 4.5 time when τ creases from 0.1 ps to 0.5 ps. Really, traband relaxation time controlled the transition between tersubband Figure. QD system conta six active layers. Figure 3. Comparison between lear absorption and emission coefficients. Copyright 011 SciRes.

68 K. H. AL-MOSSAWI ET AL. Figure 4. Ga of ZnSe/ZnS QDs. Figure 7. Small-signal ga spectra with QD layer as a parameter. Figure 5. Ga versus wavelength at several values of traband relaxation time. Figure 8. Output power versus current at values several from put power. Figure 6. Small signal ga spectrum. Figure 9. Noise figure with shot noise cluded the calculations. Copyright 011 SciRes.

K. H. AL-MOSSAWI ET AL. 69 Figure 10. noise figure with shot noise versus carrier density. 5. References [1] T. Piwonski, I. O Driscoll, J. Houlihan, G. Huyet and J. Manng, Carrier Capture Dynamics of InAs/GaAs Quantum Dot, Applied Physics letters, Vol. 90, No. 1, 007, pp.. [] T. Erneux, E. A. Viktorov, P. Mandel, T. Piwonski, G. Huyet and J. Houlihan, The Fast Recovery Dynamics of a Quantum Dot Semiconductor Optical Amplifier, Applied Physics Letters, Vol. 94, No. 11, 009, pp. 113501. doi:10.1063/1.3098361 [3] C.-J. Wang, L. Y. L and B. A. Parviz, Modelg and Simulation for a Nano-Photonic Quantum Dot Wave- guide Fabricated by DNA-Directed Self-Assembly, IEEE Journal of Selected Topics Quantum Electronics, Vol. 11, No., 005, pp.500-509. doi:10.1109/jstqe.005.845616 [4] Y. Ben-Ezra, M. Haridim and B. I. Lembrikov, Theoretical Analysis Of Ga-Recovery Time and Chirp QD-SOA, IEEE Journal of Selected Topics Quantum Electronics, Vol. 17, No. 9, 005, pp. 1803-1805. [5] M. A. Al-Mossawi, A. H. Al-Khursan, R. A. Al-Ansari, ZnO-MgZnO Quantum-Dot Semiconductor Optical Amplifiers, Recent Patents on Electrical Engeerg, Vol., No. 3, 009, pp. 6-38. doi:10.174/1874476110900306 [6] M. Vasileiadis, D. Alexandropoulos, M. J. Adams, H. Simos and D. Syvridis, Potential of InGaAs/GaAs Quantum Dots for Applications Vertical Cavity Semiconductor Optical Amplifiers IEEE Journal of Selected Topics Quantum Electronics, Vol. 14, No. 4, 008, pp. 1180-1187. doi:10.1109/jstqe.007.915517 [7] E. Forestieri, Optical Communication Theory and Techniques Ch. 8, Sprger, Pisa, 005. [8] Y. Ben-Ezra, B. I. Lembrikov and M. Haridim, Acceleration of Ga Recovery and Dynamics of Electrons QD-SOA, IEEE Journal of Selected Topics Quantum Electronics, Vol. 41, No. 10, 005, pp. 168-173. doi:10.1109/jqe.005.854131 [9] K. Veselv, F. Grillot, C. Cornet, J. Even, A. Bekiarski, M. Gianni and S. Loualiche, Analysis of the Double Laser Emission Occurrg 1.55 mm InAs-InP (133) B Quantum-Dot Lasers, IEEE Journal of Selected Topics Quantum Electronics, Vol. 43, No., 007, pp. 810-. Copyright 011 SciRes.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback