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Understanding lasers : an entry-level guide / Jeff Hecht.

By: Hecht, Jeff [author.].
Contributor(s): John Wiley & Sons [publisher.] | IEEE Xplore (Online service) [distributor.].
Material type: materialTypeLabelBookSeries: IEEE Press understanding science & technology series: 21Publisher: Piscataway, New Jersey : IEEE Press, c2008Distributor: [Piscataqay, New Jersey] : IEEE Xplore, [2012]Edition: 3rd ed.Description: 1 PDF (xiii, 478 pages) : illustrations.Content type: text Media type: electronic Carrier type: online resourceISBN: 9780470546819; 0470546816; 9780470332306.Subject(s): Lasers | Ultrafast electronics | Warranties | Wavelength measurement | Weapons | Atom lasers | Atomic beams | Cavity resonators | Chemical lasers | Coherence | Diamond-like carbon | Diffraction | Diode lasers | Educational institutions | Electromagnetic radiation | Electromagnetic scattering | Electron tubes | Energy states | Facsimile | Fiber lasers | Free electron lasers | Frequency conversion | Gamma rays | Gas lasers | Hazards | IEEE Lasers and Electro-Optics Society | IEEE Press | Indexes | Laser applications | Laser beam cutting | Laser beams | Laser excitation | Laser feedback | Laser fusion | Laser mode locking | Laser modes | Laser theory | Laser transitions | Laser tuning | Lasers | Lasers and Electro-Optics Society Newsletter | Lenses | Marketing and sales | Masers | Measurement by laser beam | Metals | Mirrors | Optical amplifiers | Optical fiber amplifiers | Optical refraction | Optics | Oscillators | Photonics | Power lasers | Presses | Pulsed laser deposition | Pump lasers | Refractive index | Resonant frequency | Ring lasers | Semiconductor diodes | Semiconductor lasers | Silicon | Solid lasers | Spectroscopy | Stimulated emission | Surface emitting lasers | Telescopes | Time frequency analysisGenre/Form: Electronic books.Additional physical formats: Print version:: No titleDDC classification: 621.36/6 Online resources: Abstract with links to resource Also available in print.
Contents:
Preface -- CHAPTER 1 Introduction and Overview -- 1.1 The Idea of the Laser -- 1.2 What is a Laser? -- 1.3 Laser Materials and Types -- 1.4 Optical Properties of Laser Light -- 1.5 How Lasers are Used -- 1.6 What Have We Learned? -- CHAPTER 2 Physical Basics -- 2.1 Electromagnetic Waves and Photons -- 2.2 Quantum and Classical Physics -- 2.3 Interactions of Light and Matter -- 2.4 Basic Optics and Simple Lenses -- 2.5 What Have We Learned? -- CHAPTER 3 How Lasers Work -- 3.1 Building a Laser -- 3.2 Producing a Population Inversion -- 3.3 Resonant Cavities -- 3.4 Laser Beams and Resonance -- 3.5 Wavelength Selection and Tuning -- 3.6 Laser Excitation Techniques -- 3.7 What Have We Learned? -- CHAPTER 4 Laser Characteristics -- 4.1 Coherence -- 4.2 Laser Wavelengths -- 4.3 Behavior of Laser Beams -- 4.4 Laser Power -- 4.5 Laser Efficiency -- 4.6 Duration of Emission -- 4.7 Polarization -- 4.8 What Have We Learned? -- CHAPTER 5 Optics and Laser Accessories -- 5.1 Classical Optical Devices -- 5.2 Transparent Optical Materials -- 5.3 Optical Surfaces, Coatings and Filters -- 5.4 Nonlinear Optics -- 5.5 Beam Intensity and Pulse Control -- 5.6 Beam Direction and Propagation -- 5.7 Mounting and Positioning Equipment -- 5.8 Optical Measurement -- 5.9 What Have We Learned? -- CHAPTER 6 Types of Lasers -- 6.1 Laser Oscillators and Optical Amplifiers -- 6.2 Laser Media -- 6.3 The Importance of Gain -- 6.4 Broadband and Wavelength-Tunable Lasers -- 6.5 Laser-Like Light Sources -- 6.6 What Have We Learned? -- CHAPTER 7 Gas Lasers -- 7.1 The Gas Laser Family -- 7.2 Gas-Laser Basics -- 7.3 Helium-Neon Lasers -- 7.4 Argon- and Krypton-Ion Lasers -- 7.5 Metal-Vapor Lasers -- 7.6 Carbon Dioxide Laser -- 7.7 Excimer Lasers -- 7.8 Chemical Lasers -- 7.9 Other Gas Lasers -- 7.10 What Have We Learned? -- CHAPTER 8 Solid-State and Fiber Lasers -- 8.1 What is a Solid-State Laser? -- 8.2 Solid-State Laser Materials -- 8.3 Optical Pumping -- 8.4 Ruby Lasers -- 8.5 Neodymium Lasers -- 8.6 Vibronic and Tunable Solid-State Lasers.
8.7 Erbium and Other Eye-Safe Laser -- 8.8 Rare-Earth-Doped Fiber Lasers -- 8.9 Rare-Earth-Doped Fiber Amplifiers -- 8.10 Raman Fiber Lasers and Amplifiers -- 8.11 What Have We Learned? -- CHAPTER 9 Semiconductor Diode Lasers -- 9.1 Basics of Semiconductor Diode Lasers -- 9.2 Semiconductor Basics -- 9.3 Light Emission at Junctions -- 9.4 Layers and Confinement in Diode Lasers -- 9.5 Confinement in the Junction Plane -- 9.6 Edge-Emitting Diode Lasers -- 9.7 Surface-Emitting Diode Lasers -- 9.8 Quantum Wells and Dots -- 9.9 Quantum Cascade Lasers -- 9.10 Optical Properties of Diode Lasers -- 9.11 Diode Laser Materials and Wavelengths -- 9.12 Silicon Lasers -- 9.13 Packaging and Specialization of Diode Lasers -- 9.14 What Have We Learned? -- CHAPTER 10 Other Lasers and Related Sources -- 10.1 Tunable Dye Lasers -- 10.2 Extreme-Ultraviolet Sources -- 10.3 Free-Electron Lasers -- 10.4 Silicon Lasers -- 10.5 What Have We Learned? -- CHAPTER 11 Low-Power Laser Applications -- 11.1 Advantages of Laser Light -- 11.2 Reading with Lasers -- 11.3 Optical Disks and Data Storage -- 11.4 Laser Printing and Marking -- 11.5 Fiber-Optic Communications -- 11.6 Laser Measurement -- 11.7 Laser Pointers, Art, and Entertainment -- 11.8 Low-Power Defense Applications -- 11.9 Sensing and Spectroscopy -- 11.10 Holography -- 11.11 Other Low-Power Applications -- 11.12 What Have We Learned? -- CHAPTER 12 High-Power Laser Applications -- 12.1 High- Versus Low-Power Laser Applications -- 12.2 Attractions of High-Power Lasers -- 12.3 Materials Working -- 12.4 Electronics Manufacturing -- 12.5 Three-Dimensional Modeling -- 12.6 Laser Medical Treatment -- 12.7 Photochemistry and Isotope Separation -- 12.8 Laser-Driven Nuclear Fusion -- 12.9 High-Energy Laser Weapons -- 12.10 Futuristic High-Power Laser Ideas -- 12.11 What Have We Learned? -- CHAPTER 13 Lasers In Research -- 13.1 Lasers Open New Opportunities -- 13.2 Laser Spectroscopy -- 13.3 Manipulating Tiny Objects -- 13.4 Atom Lasers and Bose-Einstein Condensates.
13.5 Slow Light -- 13.6 Nanoscale Lasers -- 13.7 Petawatt Lasers -- 13.8 Attosecond Pulses -- 13.9 Laser Acceleration -- 13.10 Other Emerging Research -- 13.11 What We Have Learned -- Answers to Quiz Questions -- Appendix A: Laser Safety -- Appendix B: Handy Numbers and Formulas -- Appendix C: Resources and Suggested Readings -- Glossary -- Index.
Summary: An up-to-date and easy-to-follow introduction to laser technologyLaser technology has become important in a wide range of practical applications, ranging from medicine and consumer electronics to telecommunications and military technology. Lasers are also vital tools on the cutting edge of research-eighteen recipients of the Nobel Prize received the award for laser-related research, including the laser itself, holography, laser cooling, and Bose-Einstein condensates.Updated to reflect advancements since publication of the previous edition, Understanding Lasers, Third Edition offers an introduction to lasers and associated equipment at a level that nontechnicians can fundamentally understand. The author focuses on real-world lasers and assumes only a minimal background in algebra, making the book a practical, easy-to-follow guide for a broad audience.Beginning with an overview of how lasers work, what they do, and how they're used, the book goes on to explore:. Optics and laser accessories. Semiconductor diode lasers. Gas lasers. Low-power laser applications. Solid-state and fiber lasers. High-power laser applications. Lasers in researchComplete with conceptual drawings, tables, and multiple-choice quizzes with answers provided at the back of the book, Understanding Lasers, Third Edition serves as an ideal introduction to the subject for advanced high school students, undergraduate physics and engineering students, and professionals who work with lasers but lack formal training.
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"IEEE order number PP0354-1"--T.p. verso.

Includes index.

Includes bibliographical references and index.

Preface -- CHAPTER 1 Introduction and Overview -- 1.1 The Idea of the Laser -- 1.2 What is a Laser? -- 1.3 Laser Materials and Types -- 1.4 Optical Properties of Laser Light -- 1.5 How Lasers are Used -- 1.6 What Have We Learned? -- CHAPTER 2 Physical Basics -- 2.1 Electromagnetic Waves and Photons -- 2.2 Quantum and Classical Physics -- 2.3 Interactions of Light and Matter -- 2.4 Basic Optics and Simple Lenses -- 2.5 What Have We Learned? -- CHAPTER 3 How Lasers Work -- 3.1 Building a Laser -- 3.2 Producing a Population Inversion -- 3.3 Resonant Cavities -- 3.4 Laser Beams and Resonance -- 3.5 Wavelength Selection and Tuning -- 3.6 Laser Excitation Techniques -- 3.7 What Have We Learned? -- CHAPTER 4 Laser Characteristics -- 4.1 Coherence -- 4.2 Laser Wavelengths -- 4.3 Behavior of Laser Beams -- 4.4 Laser Power -- 4.5 Laser Efficiency -- 4.6 Duration of Emission -- 4.7 Polarization -- 4.8 What Have We Learned? -- CHAPTER 5 Optics and Laser Accessories -- 5.1 Classical Optical Devices -- 5.2 Transparent Optical Materials -- 5.3 Optical Surfaces, Coatings and Filters -- 5.4 Nonlinear Optics -- 5.5 Beam Intensity and Pulse Control -- 5.6 Beam Direction and Propagation -- 5.7 Mounting and Positioning Equipment -- 5.8 Optical Measurement -- 5.9 What Have We Learned? -- CHAPTER 6 Types of Lasers -- 6.1 Laser Oscillators and Optical Amplifiers -- 6.2 Laser Media -- 6.3 The Importance of Gain -- 6.4 Broadband and Wavelength-Tunable Lasers -- 6.5 Laser-Like Light Sources -- 6.6 What Have We Learned? -- CHAPTER 7 Gas Lasers -- 7.1 The Gas Laser Family -- 7.2 Gas-Laser Basics -- 7.3 Helium-Neon Lasers -- 7.4 Argon- and Krypton-Ion Lasers -- 7.5 Metal-Vapor Lasers -- 7.6 Carbon Dioxide Laser -- 7.7 Excimer Lasers -- 7.8 Chemical Lasers -- 7.9 Other Gas Lasers -- 7.10 What Have We Learned? -- CHAPTER 8 Solid-State and Fiber Lasers -- 8.1 What is a Solid-State Laser? -- 8.2 Solid-State Laser Materials -- 8.3 Optical Pumping -- 8.4 Ruby Lasers -- 8.5 Neodymium Lasers -- 8.6 Vibronic and Tunable Solid-State Lasers.

8.7 Erbium and Other Eye-Safe Laser -- 8.8 Rare-Earth-Doped Fiber Lasers -- 8.9 Rare-Earth-Doped Fiber Amplifiers -- 8.10 Raman Fiber Lasers and Amplifiers -- 8.11 What Have We Learned? -- CHAPTER 9 Semiconductor Diode Lasers -- 9.1 Basics of Semiconductor Diode Lasers -- 9.2 Semiconductor Basics -- 9.3 Light Emission at Junctions -- 9.4 Layers and Confinement in Diode Lasers -- 9.5 Confinement in the Junction Plane -- 9.6 Edge-Emitting Diode Lasers -- 9.7 Surface-Emitting Diode Lasers -- 9.8 Quantum Wells and Dots -- 9.9 Quantum Cascade Lasers -- 9.10 Optical Properties of Diode Lasers -- 9.11 Diode Laser Materials and Wavelengths -- 9.12 Silicon Lasers -- 9.13 Packaging and Specialization of Diode Lasers -- 9.14 What Have We Learned? -- CHAPTER 10 Other Lasers and Related Sources -- 10.1 Tunable Dye Lasers -- 10.2 Extreme-Ultraviolet Sources -- 10.3 Free-Electron Lasers -- 10.4 Silicon Lasers -- 10.5 What Have We Learned? -- CHAPTER 11 Low-Power Laser Applications -- 11.1 Advantages of Laser Light -- 11.2 Reading with Lasers -- 11.3 Optical Disks and Data Storage -- 11.4 Laser Printing and Marking -- 11.5 Fiber-Optic Communications -- 11.6 Laser Measurement -- 11.7 Laser Pointers, Art, and Entertainment -- 11.8 Low-Power Defense Applications -- 11.9 Sensing and Spectroscopy -- 11.10 Holography -- 11.11 Other Low-Power Applications -- 11.12 What Have We Learned? -- CHAPTER 12 High-Power Laser Applications -- 12.1 High- Versus Low-Power Laser Applications -- 12.2 Attractions of High-Power Lasers -- 12.3 Materials Working -- 12.4 Electronics Manufacturing -- 12.5 Three-Dimensional Modeling -- 12.6 Laser Medical Treatment -- 12.7 Photochemistry and Isotope Separation -- 12.8 Laser-Driven Nuclear Fusion -- 12.9 High-Energy Laser Weapons -- 12.10 Futuristic High-Power Laser Ideas -- 12.11 What Have We Learned? -- CHAPTER 13 Lasers In Research -- 13.1 Lasers Open New Opportunities -- 13.2 Laser Spectroscopy -- 13.3 Manipulating Tiny Objects -- 13.4 Atom Lasers and Bose-Einstein Condensates.

13.5 Slow Light -- 13.6 Nanoscale Lasers -- 13.7 Petawatt Lasers -- 13.8 Attosecond Pulses -- 13.9 Laser Acceleration -- 13.10 Other Emerging Research -- 13.11 What We Have Learned -- Answers to Quiz Questions -- Appendix A: Laser Safety -- Appendix B: Handy Numbers and Formulas -- Appendix C: Resources and Suggested Readings -- Glossary -- Index.

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An up-to-date and easy-to-follow introduction to laser technologyLaser technology has become important in a wide range of practical applications, ranging from medicine and consumer electronics to telecommunications and military technology. Lasers are also vital tools on the cutting edge of research-eighteen recipients of the Nobel Prize received the award for laser-related research, including the laser itself, holography, laser cooling, and Bose-Einstein condensates.Updated to reflect advancements since publication of the previous edition, Understanding Lasers, Third Edition offers an introduction to lasers and associated equipment at a level that nontechnicians can fundamentally understand. The author focuses on real-world lasers and assumes only a minimal background in algebra, making the book a practical, easy-to-follow guide for a broad audience.Beginning with an overview of how lasers work, what they do, and how they're used, the book goes on to explore:. Optics and laser accessories. Semiconductor diode lasers. Gas lasers. Low-power laser applications. Solid-state and fiber lasers. High-power laser applications. Lasers in researchComplete with conceptual drawings, tables, and multiple-choice quizzes with answers provided at the back of the book, Understanding Lasers, Third Edition serves as an ideal introduction to the subject for advanced high school students, undergraduate physics and engineering students, and professionals who work with lasers but lack formal training.

Also available in print.

Mode of access: World Wide Web

Description based on PDF viewed 12/21/2015.

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