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Nonlinear-Emission Photonic Glass Fiber and Waveguide Devices [Kõva köide]

, (Shanghai Jiao Tong University, China)
  • Formaat: Hardback, 240 pages, kõrgus x laius x paksus: 255x178x16 mm, kaal: 650 g, Worked examples or Exercises; 223 Line drawings, black and white
  • Ilmumisaeg: 02-May-2019
  • Kirjastus: Cambridge University Press
  • ISBN-10: 1108418457
  • ISBN-13: 9781108418454
Teised raamatud teemal:
Nonlinear-Emission Photonic Glass Fiber and Waveguide DevicesSuurem pilt
  • Formaat: Hardback, 240 pages, kõrgus x laius x paksus: 255x178x16 mm, kaal: 650 g, Worked examples or Exercises; 223 Line drawings, black and white
  • Ilmumisaeg: 02-May-2019
  • Kirjastus: Cambridge University Press
  • ISBN-10: 1108418457
  • ISBN-13: 9781108418454
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781108418454.html
Märksõnad:
This book presents a comprehensive introduction to the design of compact and broadband fiber and waveguide devices using active-ion-doped photonic glasses. Combining cutting-edge theory with new applications, it shows how the complementarity of emission spectra of different active ions can be used in broadband fiber amplifiers and optical fiber communication, and describes how the quantum cutting of active ions can improve the match between the solar spectrum and the responsiveness of silicon cells. Mathematical modeling is used to predict the performance of photonic fiber and waveguide devices, and experimental data from glass doped with rare-earth ions is included. Offering unique insights into the state-of-the-art of the field, this is an ideal reference for researchers and practitioners, and invaluable reading for students in optoelectronics, electrical engineering, and materials science.

Present a comprehensive introduction to the design of compact and broadband fiber and waveguide devices using active-ion-doped photonic glasses. Covering the state-of-the-art in the field, new applications, and mathematical modeling, it is ideal for researchers, practitioners and students in optical and electrical engineering.

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Learn about the design of compact and broadband fiber and waveguide devices using active-ion-doped photonic glasses.
Preface ix
1 Fundamental Mathematics of Nonlinear-Emission Photonic Glass Fiber and Waveguide Devices
1(9)
1.1 Introduction
1(1)
1.2 Newton Iteration Algorithm for Nonlinear Rate Equation Solution
1(3)
1.2.1 Single-Variable
1(2)
1.2.2 Multi-Variable
3(1)
1.3 Runge-Kutta Algorithm for Power-Propagation Equation Solution
4(3)
1.3.1 Single-Function
4(2)
1.3.2 Multi-Functions
6(1)
1.4 Two-Point Boundary Problem for Power-Propagation Equations in a Laser Cavity
7(3)
1.4.1 Principle
7(1)
1.4.2 Shooting Method and Relaxation Method
7(2)
References
9(1)
2 Fundamental Spectral Theory of Photonic Glasses
10(6)
2.1 Introduction
10(1)
2.2 Judd-Ofelt Theory
10(2)
2.3 Transition Probability and Quantum Efficiency
12(1)
2.4 Fluorescence Branch Ratio
13(1)
2.5 Homogeneous and Inhomogeneous Broadening of Spectra
14(2)
References
15(1)
3 Spectral Properties of Ytterbium-Doped Glasses
16(49)
3.1 Introduction
16(1)
3.2 Formation Region of Yb2O3-Containing Glasses
16(1)
3.3 Laser Performance Parameters of Ytterbium-Doped Glasses
17(2)
3.3.1 Minimum Fraction of Excited State Ions
17(1)
3.3.2 Saturation Pump Intensity
18(1)
3.3.3 Minimum Pump Intensity
18(1)
3.3.4 Storage-Energy and Gain Parameters
18(1)
3.4 Spectral Properties of Yb3+-Doped Borate Glasses
19(4)
3.4.1 Compositional Dependence of Spectral Properties
19(3)
3.4.2 Dependence of Spectral Properties on Active Ion Concentration
22(1)
3.5 Spectral Properties of Yb3+-Doped Phosphate Glasses
23(5)
3.5.1 Compositional Dependence of Spectral Properties
23(3)
3.5.2 Dependence of Spectral Properties on Active Ion Concentration
26(2)
3.6 Spectral Properties of Yb3+-Doped Silicate Glasses
28(6)
3.6.1 Compositional Dependence of Spectral Properties
28(4)
3.6.2 Dependence of Spectral Properties on Active Ion Concentration
32(2)
3.7 Spectral Properties of Yb3+-Doped Germanate Glasses
34(2)
3.7.1 Compositional Dependence of Spectral Properties
34(2)
3.8 Spectral Properties of Yb3+-Doped Telluride Glasses
36(7)
3.8.1 Compositional Dependence of Spectral Properties
36(3)
3.8.2 Dependence of Spectral Properties on Active Ion Concentration
39(4)
3.9 Dependence of Spectral Property and Laser Performance Parameters on Glass System
43(8)
3.9.1 Dependence of Spectral Property on Glass Systems
43(3)
3.9.2 Dependence of Laser Performance Parameters on Glass Systems
46(5)
3.10 Dependence of Energy-Level Structure of Yb3+ on Glass Systems
51(2)
3.11 Cooperative Upconversion of Yb3+Ion Pairs
53(7)
3.11.1 Cooperative Upconversion Luminescence
53(4)
3.11.2 Concentration-Quenching Mechanics
57(2)
3.11.3 Concentration Dependence of Luminescence Intensity
59(1)
3.12 Fluorescence Trap Effect of Yb3+ Ions in Glasses
60(5)
References
63(2)
4 Compact Fiber Amplifiers
65(9)
4.1 Introduction
65(1)
4.2 Level Structure and Numerical Model
66(1)
4.3 Dependence of Gain and Noise Figure on Concentrations
67(5)
4.4 Doping Concentrations with Short-Length High Gain
72(2)
References
72(2)
5 Photonic Glass Fiber Lasers
74(17)
5.1 Introduction
74(1)
5.2 Fundamental Physics of Fiber Laser
74(6)
5.2.1 Lasing Conditions of Laser
74(1)
5.2.2 Threshold Gain
75(1)
5.2.3 Phase Condition and Laser Modes
76(1)
5.2.4 Population Inversion Calculation
76(4)
5.3 Numerical Models of Rare-Earth-Doped Fiber Lasers
80(11)
5.3.1 Configuration and Power-Propagation Equations of Fiber Laser
80(1)
5.3.2 Output Power of a Two-Level Fiber Laser
81(2)
5.3.3 Output Power of a Three-Level Fiber Laser
83(1)
5.3.4 Output Power of a Four-Level Fiber Laser
84(1)
5.3.5 Output Power of Yb3+-Doped Fiber Laser
85(5)
References
90(1)
6 Broadband Fiber Amplifiers and Sources
91(54)
6.1 Introduction
91(1)
6.2 Pr3+-Tm3+-Ex3+-Co-Doped Fiber System
92(39)
6.2.1 General Rate and Power-Propagation Equations with Two Wavelength Pumps
92(4)
6.2.2 Gain Characteristics with 980nm Pump
96(3)
6.2.3 Gain Characteristics with 793nm Pump
99(6)
6.2.4 Gain Characteristics with Double Pumps
105(26)
6.3 Gain Characteristics of Pr3+-Er3+-Co-Doped Fiber System
131(8)
6.3.1 Rate and Power-Propagation Equations
131(3)
6.3.2 Dependence of Gain on Fiber Parameters
134(5)
6.4 WDM Transmission System Cascaded with Tm3+-Er3+-Co-Doped Fiber Amplifiers
139(6)
6.4.1 WDM System with Single Pump
140(1)
6.4.2 WDM System with Dual Pumps
141(2)
References
143(2)
7 Photonic Glass Waveguides for Spectral Conversion
145(32)
7.1 Introduction
145(1)
7.2 Theoretical Model and Spectral Characterization
146(2)
7.2.1 Theoretical Model
146(2)
7.2.2 Spectral Characterization
148(1)
7.3 Doubly-Doped System
148(11)
7.3.1 Energy Transfer Model
149(3)
7.3.2 Quantum Efficiency of Photonic Glass Waveguide
152(7)
7.4 Triply-Doped System
159(12)
7.4.1 Energy Transfer Model
159(4)
7.4.2 Quantum Efficiency of Photonic Glass Waveguide
163(8)
7.5 Performance Evaluation of sc-Si-Solar Cell with Photonic Glass Waveguides
171(6)
References
174(3)
8 Photonic Glass Waveguide for White-Light Generation
177(42)
8.1 Introduction
177(1)
8.2 White-Light Glasses
178(16)
8.2.1 Tm3+-Tb3+-Eu3+-Co-Doped System
178(7)
8.2.2 Yb3+-Er3+-Tm3+-Co-Doped System
185(9)
8.3 Emission-Tunable Glasses
194(25)
8.3.1 Tb3+-Sm3+-Dy3+-Co-Doped System
194(11)
8.3.2 Tm3+-Yb3+-Ho3+-Co-Doped System
205(9)
References
214(5)
Appendix 1 Matlab Code for Solving Nonlinear Rate and Power-Propagation Equation Groups in Co-Doped Fiber Amplifiers or Fiber Sources 219(6)
Appendix 2 Matlab Code for Solving Power-Propagation Equations of a Laser Cavity with Four-Level System 225(3)
Index 228
Chun Jiang is a Professor in the Department of Electronic Engineering at Shanghai Jiao Tong University, China. Pei Song is a Lecturer in the School of Mathematics, Physics and Statistics at Shanghai University of Engineering Science.