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Story of Light Science: From Early Theories to Today's Extraordinary Applications 1st ed. 2017 [Hardback]

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  • Format: Hardback, 332 pages, height x width: 235x155 mm, weight: 6447 g, 5 Illustrations, color; 213 Illustrations, black and white; XIV, 332 p. 218 illus., 5 illus. in color., 1 Hardback
  • Pub. Date: 16-Aug-2017
  • Publisher: Springer International Publishing AG
  • ISBN-10: 3319643150
  • ISBN-13: 9783319643151
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Story of Light Science: From Early Theories to Today's Extraordinary Applications 1st ed. 2017Larger Image
  • Format: Hardback, 332 pages, height x width: 235x155 mm, weight: 6447 g, 5 Illustrations, color; 213 Illustrations, black and white; XIV, 332 p. 218 illus., 5 illus. in color., 1 Hardback
  • Pub. Date: 16-Aug-2017
  • Publisher: Springer International Publishing AG
  • ISBN-10: 3319643150
  • ISBN-13: 9783319643151
Other books in subject:
Permanent link: https://www.kriso.ee/db/9783319643151.html
Keywords:
This book traces the evolution of our understanding and utilization of light from classical antiquity and the early thoughts of Pythagoras to the present time.  

From the earliest recorded theories and experiments to the latest applications in photonic communication and computation, the ways in which light has been put to use are numerous and astounding.  Indeed, some of the latest advances in light science are in fields  that until recently belonged to the realm of science fiction.

 The author, writing for an audience of both students and other scientifically interested readers, describes fundamental investigations of the nature of light and ongoing methods to measure its speed as well as the emergence of the wave theory of light and the complementary photon theory.  The importance of light in the theory of relativity is discussed as is the development of electrically-driven light sources and lasers. The information here covers the range o

f weak single-photon light sources to super-high power lasers and synchrotron light sources.

 Many cutting-edge topics are also introduced, including entanglement-based quantum communication through optical fibers and free space, quantum teleportation, and quantum computing. The nature and use of "squeezed light" - e.g. for gravitational wave detection - is another fascinating excursion, as is the topic of fabricated metamaterials, as used to create invisibility cloaks. Here the reader also learns about the realization of extremely slow speed and time-reversed light.

The theories, experiments, and applications described in this book are, whenever possible, derived from original references.  The many annotated drawings and level of detail make clear the goals, procedures, and conclusions of the original investigators. Where they are required, all specialist terms and mathematical symbols are defined and explained.

The final part of the book covers light expe

riments in the free space of the cosmos, and also speculates about scenarios for the cosmological origins of light and the expected fate of the photon in a dying universe.

Reviews

Vanderwerf (NASA) here chronicles the evolution of our understanding of the physical phenomenon of light. ... The text combines theory and experiment, balancing the two particularly well in chapters  devoted to the tremendous applications of laser light and to the more recent applications in the storage and transmission of data. ... several diagrams and graphs illustrate the  concepts discussed. Summing Up: Recommended. Upper-division undergraduates and above; faculty and professionals. (N. Sadanand, Choice, Vol. 55 (9), May, 2018)

1 Emerging Theories of Light and Measurements of Light Speed
1(12)
1.1 Theories of Light in Classical Antiquity
1(1)
1.2 From Kepler Through Bartholinus
2(1)
1.3 Newton's Corpuscular Theory of Light
2(1)
1.4 Other Investigations on the Nature of Light
3(1)
1.5 Emergence of the Wave Theory of Light
3(1)
1.6 Experimental Speed of Light Measurements
4(9)
1.6.1 Galileo and the Speed of Light
4(2)
1.6.2 The Measurements of Romer
6(1)
1.6.3 Speed of Light Measurement by Bradley
6(2)
1.6.4 Speed of Light Measurement by Fizeau
8(1)
1.6.5 Speed of Light Measurements by Foucault
9(1)
1.6.6 Speed of Light Measurements by Michelson
10(1)
1.6.7 A Highly-Accurate Speed of Light Measurement
11(1)
References
12(1)
2 Light as an Electromagnetic Wave
13(10)
2.1 The Development of Classical Electrodynamics
13(2)
2.2 The Experiment of Weber and Kohlrausch
15(1)
2.3 Maxwell and Electromagnetism
15(3)
2.3.1 Maxwell's Electromagnetic Equations
15(2)
2.3.2 The Electromagnetic Wave Equations
17(1)
2.4 The Experiments of Hertz
18(1)
2.5 The Discovery of X-Rays
18(1)
2.6 The Electromagnetic Spectrum
19(1)
2.7 Polarization of Light
20(3)
References
21(2)
3 Light and Its Application to Relativity
23(26)
3.1 Light Speed in the Fizeau Moving Medium Experiment
23(1)
3.2 The 1887 Experiment of Michelson and Morley
24(4)
3.3 Lorentz-FitzGerald Contraction
28(1)
3.4 Lorentz Transformations
29(2)
3.5 Einstein Special Theory of Relativity
31(2)
3.6 Minkowski Spacetime
33(3)
3.6.1 The Light Cone
33(2)
3.6.2 The Invariance of Spacetime
35(1)
3.7 The Speed of Light and Einstein's E = mc2
36(1)
3.7.1 Derivations of E = mc2
36(1)
3.7.2 Relativistic Energy, Momentum, and Mass of a Photon Particle
37(1)
3.8 Einstein General Theory of Relativity
37(1)
3.9 Experimental Affirmations of Relativity
38(7)
3.9.1 The Kennedy-Thorndike Experiment
38(1)
3.9.2 Transverse Doppler Shift
39(2)
3.9.3 Time Dilation and Muon Lifetime
41(1)
3.9.4 Time Dilation and Moving Atomic Clocks
42(1)
3.9.5 Time Dilation in GPS Satellite Clocks
43(1)
3.9.6 Detection of Lorentz Length Contraction
43(1)
3.9.7 Bending of Light by the Sun
44(1)
3.10 Source Motion and the Constancy of the Speed of Light
45(4)
References
47(2)
4 The Quantum Nature of Light
49(10)
4.1 The Photoelectric Effect
49(1)
4.2 Quantum Blackbody Radiation
50(3)
4.2.1 Wien's Displacement Law
50(1)
4.2.2 Development of the Radiation Distribution Laws
51(2)
4.3 Light as a Quantized Particle
53(2)
4.3.1 The Photon as a Quantized Particle
53(1)
4.3.2 Explanation of the Photoelectric Effect
53(2)
4.4 Stimulated Emission of Einstein
55(1)
4.5 The Experiment of Compton and the Compton Effect
55(2)
4.6 The de Broglie Wavelength
57(1)
4.7 Wave-Particle Duality
57(2)
References
58(1)
5 Natural and Artificial Sources of Light
59(16)
5.1 The Sun
59(2)
5.2 Electrically-Driven Light Sources
61(9)
5.2.1 Arc-Discharge Lamps
61(2)
5.2.2 Incandescent Lamps
63(2)
5.2.3 Light-Emitting Diodes
65(2)
5.2.4 Organic Light-Emitting Diodes
67(1)
5.2.5 Quantum Dot Light-Emitting Diodes
68(2)
5.2.6 Light Emission Using Photonic Crystals
70(1)
5.3 Synchrotron Radiation Light Source
70(5)
References
72(3)
6 Laser Light
75(58)
6.1 Theoretical Foundations
75(6)
6.1.1 Stimulated Emission and Population Inversion
75(2)
6.1.2 Construction of a Laser
77(3)
6.1.3 Temporal and Spatial Coherence
80(1)
6.2 Fundamental Laser Types
81(10)
6.2.1 The Pulsed Ruby Laser
81(2)
6.2.2 The Nd: YAG Laser
83(1)
6.2.3 The Helium-Neon Laser
84(2)
6.2.4 The CO2 Laser
86(1)
6.2.5 The Argon Ion Laser
86(1)
6.2.6 The Excimer Laser
87(2)
6.2.7 The Dye Laser
89(2)
6.3 Semiconductor Laser Diodes
91(4)
6.3.1 Edge-Emitting and Quantum Well Laser Diodes
91(2)
6.3.2 Vertical Plane Emitting Laser Diodes
93(1)
6.3.3 Laser Diode Pumped Solid-State Lasers
94(1)
6.4 Some Lasers with Special Properties
95(23)
6.4.1 Fiber Lasers
95(2)
6.4.2 Doped Fiber Amplifiers
97(1)
6.4.3 Thin Disc Lasers
98(2)
6.4.4 Quantum Cascade Lasers
100(2)
6.4.5 Tunable Lasers and Linewidth
102(2)
6.4.6 Fast and Ultrafast Pulsed Lasers
104(4)
6.4.7 Surface Plasmons and Nanolasers
108(6)
6.4.8 Ultra-High Power and Energy-Pulsed Lasers
114(4)
6.5 Some Additional Laser Types
118(15)
6.5.1 Free-Electron Lasers
118(1)
6.5.2 Pulsed X-Ray Lasers
119(2)
6.5.3 Visible Color Laser
121(1)
6.5.4 White Light, Supercontinuum, and Multi-frequency Lasers
121(3)
6.5.5 Random Illumination Laser
124(1)
6.5.6 Dark Pulse Lasers
125(1)
6.5.7 Coupled Lasers
126(1)
6.5.8 Biological Laser
127(1)
6.5.9 Time-Reversed Lasing and Anti-lasers
128(1)
6.5.10 Superradiant Laser
128(1)
References
129(4)
7 Variation and Control of Light Propagation Properties
133(40)
7.1 Slowing the Speed of Light
133(13)
7.1.1 Refractive Index
133(1)
7.1.2 Phase Velocity and Group Velocity
133(2)
7.1.3 Some Slow Light Methodologies
135(2)
7.1.4 Thermal deBroglie Wavelength and Bose-Einstein Condensates
137(3)
7.1.5 Extreme Reduction of Light Speed in a Super-Cooled Atomic Gas
140(2)
7.1.6 Ultraslow Light Propagation in Higher Temperature Atomic Gases
142(2)
7.1.7 Slow Light Using Photonic Crystals
144(2)
7.2 Stopped Light and Storage of Light Pulses
146(1)
7.3 Time-Reversed Light Using a Photonic Crystal
147(1)
7.4 Exceeding the Cosmic Speed of Light in a Medium
148(3)
7.4.1 The Speed of Light and Causality
148(1)
7.4.2 Superluminal Light in Dispersive Media
149(2)
7.5 Light Path Manipulation
151(22)
7.5.1 Light Propagation and Negative Refraction
151(5)
7.5.2 Infinite Light Speed Using a Zero Refractive Index Medium
156(2)
7.5.3 Invisibility Cloaking and Transformation Optics
158(9)
7.5.4 Spacetime Hidden Event Cloaking
167(3)
References
170(3)
8 Quantum Mechanics of the Photon
173(62)
8.1 Double-Slit Experiments Using Photon Particles
173(1)
8.2 Delayed-Choice Experiments
174(15)
8.2.1 The Delayed-Choice Experiment of Wheeler
174(2)
8.2.2 Experimental Realization of Delayed-Choice
176(3)
8.2.3 EPR Paradox, Particle Entanglement, and Bell's Inequalities
179(1)
8.2.4 Experimental Verification of Photon Entanglement
179(1)
8.2.5 A Quantum Mechanical Beamsplitter
180(2)
8.2.6 Delayed-Choice Quantum Eraser
182(4)
8.2.7 Quantum Interference Between Indistinguishable Photons
186(1)
8.2.8 Observation of Photon Wave-Particle Transitions
187(2)
8.3 Quantum Electrodynamics and the Photon
189(3)
8.4 The Casimir Effect and Virtual Photons
192(5)
8.5 Quantum Correlations of Single and Multiple Photons
197(16)
8.5.1 Single-Photon Particle Anticorrelation
197(2)
8.5.2 Single-Photon Entanglement
199(2)
8.5.3 Validation of Single-Photon Nonlocality
201(5)
8.5.4 Higher-Order Photon Entanglements
206(3)
8.5.5 Four-Photon Entanglement
209(1)
8.5.6 Six-Photon and Eight-Photon Entanglements
210(2)
8.5.7 Entanglement of Non-coexistent Photons
212(1)
8.6 Photon Tunneling and Superluminality
213(4)
8.7 Two-Photon Interactions
217(3)
8.8 Squeezed Light, Squeezed Vacuum, and Gravitational Wave Detection
220(3)
8.9 Non-destructive Observation of the Photon
223(2)
8.10 Quantum Zeno Effect for Photons
225(2)
8.11 Observation of Photon Trajectories
227(1)
8.12 Creation of Matter by Colliding Photons
228(2)
8.13 Gauge Theory and Size of the Photon
230(5)
References
231(4)
9 Quantum Applications of the Photon
235(66)
9.1 Entanglement-Enhanced Quantum Communication
235(3)
9.1.1 Theoretical Foundation
235(1)
9.1.2 Experimental Quantum Communication Using Dense Coding
235(3)
9.2 Encrypted Quantum Communication Using Photons
238(11)
9.2.1 Quantum Cryptography Protocols
238(2)
9.2.2 Single-Photon Beam for Secure Quantum Communication
240(1)
9.2.3 Ideal Properties of a Pulsed Single-Photon Light Source
240(1)
9.2.4 Single-Photon Light Source Using Diamond Nanocrystals
241(1)
9.2.5 Single-Photon Light Source Using a Whispering Gallery
242(2)
9.2.6 Other Room Temperature Single-Photon Light Sources
244(2)
9.2.7 Single-Photon Detectors for Encrypted Photons
246(2)
9.2.8 Secure Quantum Communication Through Free-Space
248(1)
9.3 Ultra-High Data Transmission Using Photons
249(3)
9.3.1 Angular Momentum of a Photon
249(1)
9.3.2 Data Transmission Through Free-Space Using OAM Photons
250(1)
9.3.3 Ultra-Fast Data Transmission Through Optical Fibers Using Photons
251(1)
9.4 Long-Range Communication Using Quantum Repeaters
252(20)
9.4.1 Quantum Memory
252(6)
9.4.2 Principles of Quantum Teleportation
258(4)
9.4.3 Quantum Teleportation Through Optical Fibers
262(3)
9.4.4 Quantum Teleportation Through Free-Space
265(2)
9.4.5 Quantum Repeaters for Long-Range Optical Fiber Transmission
267(2)
9.4.6 Photonic Quantum Networks
269(1)
9.4.7 A Quantum Internet
270(2)
9.5 Photonic Random Number Generation
272(5)
9.6 Quantum Computing Using Photons
277(13)
9.6.1 Quantum Gates Using Linear Optics
277(3)
9.6.2 Boson Sampling
280(6)
9.6.3 Quantum Computation Efficiency
286(1)
9.6.4 Deutsch and Shor Quantum Algorithms
286(2)
9.6.5 A Universal Quantum Computer Architecture
288(2)
9.7 Timelike Curves, Time Travel, and Computing
290(11)
References
295(6)
10 Light in Free-Space and the Cosmos
301(16)
10.1 The Speed of Light in the Cosmos
301(9)
10.1.1 The Cosmic Speed of Light and Planck Length
301(1)
10.1.2 Gamma-Ray Bursts and the Cosmic Speed of Light
302(1)
10.1.3 The Speed of Light and the Fine Structure Constant
302(1)
10.1.4 Isotropy of the Speed of Light in Space
303(2)
10.1.5 Slowing the Speed of Light in Free-Space
305(2)
10.1.6 Waves Exceeding the Speed of Light in Free-Space
307(2)
10.1.7 Particles Exceeding the Speed of Light in Free-Space
309(1)
10.2 The Warp Drive of Alcubierre
310(1)
10.3 Dark Matter and Gravitational Lensing
310(1)
10.4 The Cosmological Beginning of the Photon
311(1)
10.5 Temperature of the Universe and Wien's Law
312(1)
10.6 The Cosmological Fate of the Photon
313(4)
References
314(3)
Appendices 317(6)
Timeline of Some Notable Achievements in Light Science 323(2)
A Selection of Additional Readings 325(2)
Index 327
Dennis Vanderwerf has over 35 years of aerospace (NASA) and industrial experience (3M Company) in the fields of optics and light control. He has published widely in optics journals, conference proceedings, and trade magazines. He is sole or named inventor on 29 U.S. Patents in the fields of optics and light applications. He is author of the book Applied Prismatic and Reflective Optics, published in 2010 by SPIE Press.