Laser physics

In this book the interaction of radiation and matter, and the principles of laser operation are treated at a level suitable for fourth-year undergraduate courses or introductory graduate courses in physics, chemistry or engineering. The factors which determine efficiency, wavelength coverage, output power, and beam quality of the different classes of laser are treated both in terms of fundamental theory and practical construction aspects. Details of established types of solid-state, semiconductor, and gas lasers are examined together with the techniques that enable their output to be converted widely across the spectrum. The latest advances in high power fibre lasers, femtosecond lasers, and X-ray lasers are explained. The text is liberally illustrated with more than 300 diagrams. An extensive bibliography is provided, together with numerical problems in each chapter. Solutions are available via the web.

• 1. Introduction
• 2. The interaction of radiation and matter
• 3. Broadening mechanisms and lineshapes
• 4. Light Amplification by the Stimulated Emission of Radi- ation
• 5. Gain saturation
• 6. The laser oscillator
• 7. Solid-state lasers
• 8. Dynamic Cavity Effects
• 9. Semiconductor Lasers
• 10. Fibre Lasers
• 11. Atomic Gas Lasers
• 12. Infra-red molecular gas lasers
• 13. Ultraviolet Molecular Gas Lasers
• 14. Dye Lasers
• 15. Nonlinear frequency conversi
• 16. Precision frequency control of lasers
• 17. Ultrafast lasers
• 18. Short-wavelength lasers
• Appendix A Semi-classical theory
• Appendix B The Spectral Einstein Coefficients
• Appendix C Kleinman's conjecture

In this book the interaction of radiation and matter, and the principles of laser operation are treated at a level suitable for fourth-year undergraduate courses or introductory graduate courses in physics, chemistry or engineering. The factors which determine efficiency, wavelength coverage, output power, and beam quality of the different classes of laser are treated both in terms of fundamental theory and practical construction aspects. Details of established types of solid-state, semiconductor, and gas lasers are examined together with the techniques that enable their output to be converted widely across the spectrum. The latest advances in high power fibre lasers, femtosecond lasers, and X-ray lasers are explained. The text is liberally illustrated with more than 300 diagrams. An extensive bibliography is provided, together with numerical problems in each chapter. Solutions are available via the web.

• 1. Introduction
• 2. The interaction of radiation and matter
• 3. Broadening mechanisms and lineshapes
• 4. Light Amplification by the Stimulated Emission of Radi- ation
• 5. Gain saturation
• 6. The laser oscillator
• 7. Solid-state lasers
• 8. Dynamic Cavity Effects
• 9. Semiconductor Lasers
• 10. Fibre Lasers
• 11. Atomic Gas Lasers
• 12. Infra-red molecular gas lasers
• 13. Ultraviolet Molecular Gas Lasers
• 14. Dye Lasers
• 15. Nonlinear frequency conversi
• 16. Precision frequency control of lasers
• 17. Ultrafast lasers
• 18. Short-wavelength lasers
• Appendix A Semi-classical theory
• Appendix B The Spectral Einstein Coefficients
• Appendix C Kleinman's conjecture