Alain Boutier
Laser Metrology in Fluid Mechanics
Granulometry, Temperature and Concentration Measurements
Alain Boutier
Laser Metrology in Fluid Mechanics
Granulometry, Temperature and Concentration Measurements
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In fluid mechanics, non-intrusive measurements are fundamental in order to improve knowledge of the behavior and main physical phenomena of flows in order to further validate codes. The principles and characteristics of the different techniques available in laser metrology are described in detail in this book. Velocity, temperature and concentration measurements by spectroscopic techniques based on light scattered by molecules are achieved by different techniques: laser-induced fluorescence, coherent anti-Stokes Raman scattering using lasers and parametric sources, and absorption spectroscopy…mehr
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In fluid mechanics, non-intrusive measurements are fundamental in order to improve knowledge of the behavior and main physical phenomena of flows in order to further validate codes.
The principles and characteristics of the different techniques available in laser metrology are described in detail in this book.
Velocity, temperature and concentration measurements by spectroscopic techniques based on light scattered by molecules are achieved by different techniques: laser-induced fluorescence, coherent anti-Stokes Raman scattering using lasers and parametric sources, and absorption spectroscopy by tunable laser diodes, which are generally better suited for high velocity flows. The size determination of particles by optical means, a technique mainly applied in two-phase flows, is the subject of another chapter, along with a description of the principles of light scattering.
For each technique the basic principles are given, as well as optical devices and data processing. A final chapter reminds the reader of the main safety precautions to be taken when using powerful lasers.
The principles and characteristics of the different techniques available in laser metrology are described in detail in this book.
Velocity, temperature and concentration measurements by spectroscopic techniques based on light scattered by molecules are achieved by different techniques: laser-induced fluorescence, coherent anti-Stokes Raman scattering using lasers and parametric sources, and absorption spectroscopy by tunable laser diodes, which are generally better suited for high velocity flows. The size determination of particles by optical means, a technique mainly applied in two-phase flows, is the subject of another chapter, along with a description of the principles of light scattering.
For each technique the basic principles are given, as well as optical devices and data processing. A final chapter reminds the reader of the main safety precautions to be taken when using powerful lasers.
Produktdetails
- Produktdetails
- ISTE .
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 368
- Erscheinungstermin: 26. Dezember 2012
- Englisch
- Abmessung: 234mm x 157mm x 23mm
- Gewicht: 658g
- ISBN-13: 9781848213982
- ISBN-10: 1848213980
- Artikelnr.: 34789119
- ISTE .
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 368
- Erscheinungstermin: 26. Dezember 2012
- Englisch
- Abmessung: 234mm x 157mm x 23mm
- Gewicht: 658g
- ISBN-13: 9781848213982
- ISBN-10: 1848213980
- Artikelnr.: 34789119
Alain Boutier is Assistant of the General Scientific Director at Office National d'Etudes et de Recherches Aérospatiales (ONERA), Palaiseau, France.
Preface xi Introduction xiii Alain BOUTIER Chapter 1. Basics on Light
Scattering by Particles 1 Fabrice ONOFRI and Séverine BARBOSA 1.1.
Introduction 1 1.2. A brief synopsis of electromagnetic theory 2 1.2.1.
Maxwell's equations 2 1.2.2. Harmonic electromagnetic plane waves 4 1.2.3.
Optical constants 9 1.2.4. Light scattering by a single particle 11 1.3.
Methods using separation of variables 16 1.3.1. Lorenz-Mie (or Mie) theory
16 1.3.2. Debye and complex angular momentum theories 26 1.4. Rayleigh
theory and the discrete dipole approximation 29 1.4.1. Rayleigh theory 29
1.4.2. Discrete dipole approximation 31 1.5. The T-matrix method 32 1.6.
Physical (or wave) optics models 34 1.6.1. Huygens-Fresnel integral 35
1.6.2. Fraunhofer diffraction theory for a particle with a circular cross
section 37 1.6.3. Airy theory of the rainbow 40 1.6.4. Marston's
physical-optics approximation 44 1.7. Geometrical optics 47 1.7.1.
Calculation of the scattering angle 48 1.7.2. Calculation of the intensity
of rays 48 1.7.3. Calculation of the phase and amplitude of rays 49 1.8.
Multiple scattering and Monte Carlo models 50 1.8.1. Scattering by an
optically diluted particle system 50 1.8.2. Multiple scattering 51 1.8.3.
Monte Carlo method 52 1.9. Conclusion 57 1.10. Bibliography 57 Chapter 2.
Optical Particle Characterization 67 Fabrice ONOFRI and Séverine BARBOSA
2.1. Introduction 67 2.2. Particles in flows 69 2.2.1. Diameter, shape and
concentration 69 2.2.2. Statistical representation of particle size data 70
2.2.3. Concentrations and fluxes 74 2.3. An attempt to classify OPC
techniques 75 2.3.1. Physical principles and measured quantities 75 2.3.2.
Nature and procedure to achieve statistics 76 2.4. Phase Doppler
interferometry (or anemometry) 77 2.4.1. Principle 77 2.4.2. Modeling the
phase-diameter relationship 81 2.4.3. Experimental setup and typical
results 87 2.4.4. Conclusion 90 2.5. Ellipsometry 91 2.6. Forward (or
"laser") diffraction 93 2.6.1. Principle 93 2.6.2. Modeling and inversion
of diffraction patterns 95 2.6.3. Typical experimental setup and results 98
2.6.4. Conclusion 100 2.7. Rainbow and near-critical-angle diffractometry
techniques 101 2.7.1. Similarities to forward diffraction 101 2.7.2.
Rainbow diffractometry 102 2.7.3. Near-critical-angle diffractometry 107
2.8. Classical shadowgraph imaging 112 2.8.1. Principle and classical setup
112 2.8.2. One-dimensional shadow Doppler technique 114 2.8.3. Calculation
of particle images using the point spread function 115 2.8.4. Conclusion
118 2.9. Out-of-focus interferometric imaging 119 2.9.1. Principle 119
2.9.2. Modeling the diameter-angular frequency relationship 120 2.9.3.
Conclusion 126 2.10. Holography of particles 128 2.10.1. Gabor holography
for holographic films 128 2.10.2. Inline digital holography 129 2.10.3.
Conclusion 131 2.11. Light extinction spectrometry 132 2.11.1. Principle
132 2.11.2. Algebraic inverse method 134 2.11.3. Experimental setup and
conclusion 136 2.12. Photon correlation spectroscopy 139 2.13.
Laser-induced fluorescence and elastic-scattering imaging ratio 141 2.13.1.
Principle 142 2.13.2. Experimental setup and results 143 2.13.3. Conclusion
144 2.14. Laser-induced incandescence 144 2.15. General conclusions 145
2.16. Bibliography 146 Chapter 3. Laser-Induced Fluorescence 159 Fabrice
LEMOINE and Frédéric GRISCH 3.1. Recall on energy quantification of
molecules 159 3.1.1. Radiative transitions 162 3.1.2. Energy level
thermo-statistics 164 3.1.3. Franck-Condon principle 164 3.1.4.
Non-radiative transitions 164 3.1.5. Line width 165 3.2. Laser-induced
fluorescence principles 168 3.2.1. Absorption kinetics 169 3.2.2.
Fluorescence signal 170 3.2.3. Fluorescence detection 173 3.2.4. Absorption
along optical path 174 3.2.5. Fluorescence measurement device 175 3.3.
Applications of laser-induced fluorescence in gases 177 3.3.1. Generalities
177 3.3.2. Diatomic molecules 178 3.3.3. Poly-Atomic molecular tracers 186
3.4. Laser-induced fluorescence in liquids 202 3.4.1. Principles and
modeling 202 3.4.2. Fluorescence reabsorption 205 3.4.3. Applications to
concentration measurement 205 3.4.4. Application to temperature measurement
210 3.5. Bibliography 218 Chapter 4. Diode Laser Absorption Spectroscopy
Techniques 223 Ajmal MOHAMED 4.1. High spectral resolution absorption
spectroscopy in fluid mechanics 223 4.2. Recap on molecular absorption 226
4.2.1. Line profile 226 4.2.2. Line strength 228 4.3. Absorption
spectroscopy bench 229 4.3.1. Emitting optics 230 4.3.2. Optical detection
234 4.3.3. Spectra processing 237 4.4. Applications in hypersonic 245
4.4.1. F4 characteristics 246 4.4.2. Setup installed at F4 248 4.4.3.
Results obtained at F4 and HEG 249 4.5. Other applications of diode laser
absorption spectroscopy 250 4.5.1. Combustion applications 250 4.5.2.
Applications to atmospheric probing 253 4.6. Other devices for diode laser
absorption spectroscopy 254 4.6.1. Multipass spectrometry 254 4.6.2.
Spectrometry in a resonant cavity 257 4.7. Perspectives and conclusion on
diode laser absorption spectroscopy 261 4.7.1. Laser source: use of
non-cryogenic diodes 262 4.7.2. Spatial resolution: use of probe in flow
262 4.7.3. Use of frequency combs 264 4.8. Bibliography 264 Chapter 5.
Nonlinear Optical Sources and Techniques for Optical Diagnostic 271 Michel
LEFEBVRE 5.1. Introduction to nonlinear optics 271 5.2. Main processes in
nonlinear optics 272 5.2.1. Propagation effects 273 5.2.2. Second- and
third-order nonlinearities 276 5.2.3. Phase matching notion 280 5.3.
Nonlinear sources for optical metrology 282 5.3.1. Sum frequency generation
and frequency doubling 283 5.3.2. Raman converters 285 5.3.3. Optical
parametric generators and oscillators 289 5.4. Nonlinear techniques for
optical diagnostic 296 5.4.1. Introduction to four-wave mixing techniques
296 5.4.2. Temperature and concentration measurements in four-wave mixing
299 5.4.3. Velocity measurements in four-wave mixing 301 5.5. Bibliography
305 Chapter 6. Laser Safety 307 Jean-Michel MOST 6.1. Generalities on laser
safety 307 6.2. Laser type and classification 308 6.3. Laser risks: nature
and effects 310 6.3.1. Biological risks 310 6.3.2. Risks to the eye 312
6.3.3. Risks to the skin 314 6.3.4. Risk to hearing 315 6.3.5. Other
biological risks 315 6.4. Protections 316 6.4.1. Accident prevention 316
6.4.2. Collective protection 316 6.4.3. Individual protection 318 6.5.
Safety advice 319 6.6. Human behavior 320 Conclusion 321 Alain BOUTIER
Nomenclature 323 List of Authors 329 Index 331
Scattering by Particles 1 Fabrice ONOFRI and Séverine BARBOSA 1.1.
Introduction 1 1.2. A brief synopsis of electromagnetic theory 2 1.2.1.
Maxwell's equations 2 1.2.2. Harmonic electromagnetic plane waves 4 1.2.3.
Optical constants 9 1.2.4. Light scattering by a single particle 11 1.3.
Methods using separation of variables 16 1.3.1. Lorenz-Mie (or Mie) theory
16 1.3.2. Debye and complex angular momentum theories 26 1.4. Rayleigh
theory and the discrete dipole approximation 29 1.4.1. Rayleigh theory 29
1.4.2. Discrete dipole approximation 31 1.5. The T-matrix method 32 1.6.
Physical (or wave) optics models 34 1.6.1. Huygens-Fresnel integral 35
1.6.2. Fraunhofer diffraction theory for a particle with a circular cross
section 37 1.6.3. Airy theory of the rainbow 40 1.6.4. Marston's
physical-optics approximation 44 1.7. Geometrical optics 47 1.7.1.
Calculation of the scattering angle 48 1.7.2. Calculation of the intensity
of rays 48 1.7.3. Calculation of the phase and amplitude of rays 49 1.8.
Multiple scattering and Monte Carlo models 50 1.8.1. Scattering by an
optically diluted particle system 50 1.8.2. Multiple scattering 51 1.8.3.
Monte Carlo method 52 1.9. Conclusion 57 1.10. Bibliography 57 Chapter 2.
Optical Particle Characterization 67 Fabrice ONOFRI and Séverine BARBOSA
2.1. Introduction 67 2.2. Particles in flows 69 2.2.1. Diameter, shape and
concentration 69 2.2.2. Statistical representation of particle size data 70
2.2.3. Concentrations and fluxes 74 2.3. An attempt to classify OPC
techniques 75 2.3.1. Physical principles and measured quantities 75 2.3.2.
Nature and procedure to achieve statistics 76 2.4. Phase Doppler
interferometry (or anemometry) 77 2.4.1. Principle 77 2.4.2. Modeling the
phase-diameter relationship 81 2.4.3. Experimental setup and typical
results 87 2.4.4. Conclusion 90 2.5. Ellipsometry 91 2.6. Forward (or
"laser") diffraction 93 2.6.1. Principle 93 2.6.2. Modeling and inversion
of diffraction patterns 95 2.6.3. Typical experimental setup and results 98
2.6.4. Conclusion 100 2.7. Rainbow and near-critical-angle diffractometry
techniques 101 2.7.1. Similarities to forward diffraction 101 2.7.2.
Rainbow diffractometry 102 2.7.3. Near-critical-angle diffractometry 107
2.8. Classical shadowgraph imaging 112 2.8.1. Principle and classical setup
112 2.8.2. One-dimensional shadow Doppler technique 114 2.8.3. Calculation
of particle images using the point spread function 115 2.8.4. Conclusion
118 2.9. Out-of-focus interferometric imaging 119 2.9.1. Principle 119
2.9.2. Modeling the diameter-angular frequency relationship 120 2.9.3.
Conclusion 126 2.10. Holography of particles 128 2.10.1. Gabor holography
for holographic films 128 2.10.2. Inline digital holography 129 2.10.3.
Conclusion 131 2.11. Light extinction spectrometry 132 2.11.1. Principle
132 2.11.2. Algebraic inverse method 134 2.11.3. Experimental setup and
conclusion 136 2.12. Photon correlation spectroscopy 139 2.13.
Laser-induced fluorescence and elastic-scattering imaging ratio 141 2.13.1.
Principle 142 2.13.2. Experimental setup and results 143 2.13.3. Conclusion
144 2.14. Laser-induced incandescence 144 2.15. General conclusions 145
2.16. Bibliography 146 Chapter 3. Laser-Induced Fluorescence 159 Fabrice
LEMOINE and Frédéric GRISCH 3.1. Recall on energy quantification of
molecules 159 3.1.1. Radiative transitions 162 3.1.2. Energy level
thermo-statistics 164 3.1.3. Franck-Condon principle 164 3.1.4.
Non-radiative transitions 164 3.1.5. Line width 165 3.2. Laser-induced
fluorescence principles 168 3.2.1. Absorption kinetics 169 3.2.2.
Fluorescence signal 170 3.2.3. Fluorescence detection 173 3.2.4. Absorption
along optical path 174 3.2.5. Fluorescence measurement device 175 3.3.
Applications of laser-induced fluorescence in gases 177 3.3.1. Generalities
177 3.3.2. Diatomic molecules 178 3.3.3. Poly-Atomic molecular tracers 186
3.4. Laser-induced fluorescence in liquids 202 3.4.1. Principles and
modeling 202 3.4.2. Fluorescence reabsorption 205 3.4.3. Applications to
concentration measurement 205 3.4.4. Application to temperature measurement
210 3.5. Bibliography 218 Chapter 4. Diode Laser Absorption Spectroscopy
Techniques 223 Ajmal MOHAMED 4.1. High spectral resolution absorption
spectroscopy in fluid mechanics 223 4.2. Recap on molecular absorption 226
4.2.1. Line profile 226 4.2.2. Line strength 228 4.3. Absorption
spectroscopy bench 229 4.3.1. Emitting optics 230 4.3.2. Optical detection
234 4.3.3. Spectra processing 237 4.4. Applications in hypersonic 245
4.4.1. F4 characteristics 246 4.4.2. Setup installed at F4 248 4.4.3.
Results obtained at F4 and HEG 249 4.5. Other applications of diode laser
absorption spectroscopy 250 4.5.1. Combustion applications 250 4.5.2.
Applications to atmospheric probing 253 4.6. Other devices for diode laser
absorption spectroscopy 254 4.6.1. Multipass spectrometry 254 4.6.2.
Spectrometry in a resonant cavity 257 4.7. Perspectives and conclusion on
diode laser absorption spectroscopy 261 4.7.1. Laser source: use of
non-cryogenic diodes 262 4.7.2. Spatial resolution: use of probe in flow
262 4.7.3. Use of frequency combs 264 4.8. Bibliography 264 Chapter 5.
Nonlinear Optical Sources and Techniques for Optical Diagnostic 271 Michel
LEFEBVRE 5.1. Introduction to nonlinear optics 271 5.2. Main processes in
nonlinear optics 272 5.2.1. Propagation effects 273 5.2.2. Second- and
third-order nonlinearities 276 5.2.3. Phase matching notion 280 5.3.
Nonlinear sources for optical metrology 282 5.3.1. Sum frequency generation
and frequency doubling 283 5.3.2. Raman converters 285 5.3.3. Optical
parametric generators and oscillators 289 5.4. Nonlinear techniques for
optical diagnostic 296 5.4.1. Introduction to four-wave mixing techniques
296 5.4.2. Temperature and concentration measurements in four-wave mixing
299 5.4.3. Velocity measurements in four-wave mixing 301 5.5. Bibliography
305 Chapter 6. Laser Safety 307 Jean-Michel MOST 6.1. Generalities on laser
safety 307 6.2. Laser type and classification 308 6.3. Laser risks: nature
and effects 310 6.3.1. Biological risks 310 6.3.2. Risks to the eye 312
6.3.3. Risks to the skin 314 6.3.4. Risk to hearing 315 6.3.5. Other
biological risks 315 6.4. Protections 316 6.4.1. Accident prevention 316
6.4.2. Collective protection 316 6.4.3. Individual protection 318 6.5.
Safety advice 319 6.6. Human behavior 320 Conclusion 321 Alain BOUTIER
Nomenclature 323 List of Authors 329 Index 331
Preface xi Introduction xiii Alain BOUTIER Chapter 1. Basics on Light
Scattering by Particles 1 Fabrice ONOFRI and Séverine BARBOSA 1.1.
Introduction 1 1.2. A brief synopsis of electromagnetic theory 2 1.2.1.
Maxwell's equations 2 1.2.2. Harmonic electromagnetic plane waves 4 1.2.3.
Optical constants 9 1.2.4. Light scattering by a single particle 11 1.3.
Methods using separation of variables 16 1.3.1. Lorenz-Mie (or Mie) theory
16 1.3.2. Debye and complex angular momentum theories 26 1.4. Rayleigh
theory and the discrete dipole approximation 29 1.4.1. Rayleigh theory 29
1.4.2. Discrete dipole approximation 31 1.5. The T-matrix method 32 1.6.
Physical (or wave) optics models 34 1.6.1. Huygens-Fresnel integral 35
1.6.2. Fraunhofer diffraction theory for a particle with a circular cross
section 37 1.6.3. Airy theory of the rainbow 40 1.6.4. Marston's
physical-optics approximation 44 1.7. Geometrical optics 47 1.7.1.
Calculation of the scattering angle 48 1.7.2. Calculation of the intensity
of rays 48 1.7.3. Calculation of the phase and amplitude of rays 49 1.8.
Multiple scattering and Monte Carlo models 50 1.8.1. Scattering by an
optically diluted particle system 50 1.8.2. Multiple scattering 51 1.8.3.
Monte Carlo method 52 1.9. Conclusion 57 1.10. Bibliography 57 Chapter 2.
Optical Particle Characterization 67 Fabrice ONOFRI and Séverine BARBOSA
2.1. Introduction 67 2.2. Particles in flows 69 2.2.1. Diameter, shape and
concentration 69 2.2.2. Statistical representation of particle size data 70
2.2.3. Concentrations and fluxes 74 2.3. An attempt to classify OPC
techniques 75 2.3.1. Physical principles and measured quantities 75 2.3.2.
Nature and procedure to achieve statistics 76 2.4. Phase Doppler
interferometry (or anemometry) 77 2.4.1. Principle 77 2.4.2. Modeling the
phase-diameter relationship 81 2.4.3. Experimental setup and typical
results 87 2.4.4. Conclusion 90 2.5. Ellipsometry 91 2.6. Forward (or
"laser") diffraction 93 2.6.1. Principle 93 2.6.2. Modeling and inversion
of diffraction patterns 95 2.6.3. Typical experimental setup and results 98
2.6.4. Conclusion 100 2.7. Rainbow and near-critical-angle diffractometry
techniques 101 2.7.1. Similarities to forward diffraction 101 2.7.2.
Rainbow diffractometry 102 2.7.3. Near-critical-angle diffractometry 107
2.8. Classical shadowgraph imaging 112 2.8.1. Principle and classical setup
112 2.8.2. One-dimensional shadow Doppler technique 114 2.8.3. Calculation
of particle images using the point spread function 115 2.8.4. Conclusion
118 2.9. Out-of-focus interferometric imaging 119 2.9.1. Principle 119
2.9.2. Modeling the diameter-angular frequency relationship 120 2.9.3.
Conclusion 126 2.10. Holography of particles 128 2.10.1. Gabor holography
for holographic films 128 2.10.2. Inline digital holography 129 2.10.3.
Conclusion 131 2.11. Light extinction spectrometry 132 2.11.1. Principle
132 2.11.2. Algebraic inverse method 134 2.11.3. Experimental setup and
conclusion 136 2.12. Photon correlation spectroscopy 139 2.13.
Laser-induced fluorescence and elastic-scattering imaging ratio 141 2.13.1.
Principle 142 2.13.2. Experimental setup and results 143 2.13.3. Conclusion
144 2.14. Laser-induced incandescence 144 2.15. General conclusions 145
2.16. Bibliography 146 Chapter 3. Laser-Induced Fluorescence 159 Fabrice
LEMOINE and Frédéric GRISCH 3.1. Recall on energy quantification of
molecules 159 3.1.1. Radiative transitions 162 3.1.2. Energy level
thermo-statistics 164 3.1.3. Franck-Condon principle 164 3.1.4.
Non-radiative transitions 164 3.1.5. Line width 165 3.2. Laser-induced
fluorescence principles 168 3.2.1. Absorption kinetics 169 3.2.2.
Fluorescence signal 170 3.2.3. Fluorescence detection 173 3.2.4. Absorption
along optical path 174 3.2.5. Fluorescence measurement device 175 3.3.
Applications of laser-induced fluorescence in gases 177 3.3.1. Generalities
177 3.3.2. Diatomic molecules 178 3.3.3. Poly-Atomic molecular tracers 186
3.4. Laser-induced fluorescence in liquids 202 3.4.1. Principles and
modeling 202 3.4.2. Fluorescence reabsorption 205 3.4.3. Applications to
concentration measurement 205 3.4.4. Application to temperature measurement
210 3.5. Bibliography 218 Chapter 4. Diode Laser Absorption Spectroscopy
Techniques 223 Ajmal MOHAMED 4.1. High spectral resolution absorption
spectroscopy in fluid mechanics 223 4.2. Recap on molecular absorption 226
4.2.1. Line profile 226 4.2.2. Line strength 228 4.3. Absorption
spectroscopy bench 229 4.3.1. Emitting optics 230 4.3.2. Optical detection
234 4.3.3. Spectra processing 237 4.4. Applications in hypersonic 245
4.4.1. F4 characteristics 246 4.4.2. Setup installed at F4 248 4.4.3.
Results obtained at F4 and HEG 249 4.5. Other applications of diode laser
absorption spectroscopy 250 4.5.1. Combustion applications 250 4.5.2.
Applications to atmospheric probing 253 4.6. Other devices for diode laser
absorption spectroscopy 254 4.6.1. Multipass spectrometry 254 4.6.2.
Spectrometry in a resonant cavity 257 4.7. Perspectives and conclusion on
diode laser absorption spectroscopy 261 4.7.1. Laser source: use of
non-cryogenic diodes 262 4.7.2. Spatial resolution: use of probe in flow
262 4.7.3. Use of frequency combs 264 4.8. Bibliography 264 Chapter 5.
Nonlinear Optical Sources and Techniques for Optical Diagnostic 271 Michel
LEFEBVRE 5.1. Introduction to nonlinear optics 271 5.2. Main processes in
nonlinear optics 272 5.2.1. Propagation effects 273 5.2.2. Second- and
third-order nonlinearities 276 5.2.3. Phase matching notion 280 5.3.
Nonlinear sources for optical metrology 282 5.3.1. Sum frequency generation
and frequency doubling 283 5.3.2. Raman converters 285 5.3.3. Optical
parametric generators and oscillators 289 5.4. Nonlinear techniques for
optical diagnostic 296 5.4.1. Introduction to four-wave mixing techniques
296 5.4.2. Temperature and concentration measurements in four-wave mixing
299 5.4.3. Velocity measurements in four-wave mixing 301 5.5. Bibliography
305 Chapter 6. Laser Safety 307 Jean-Michel MOST 6.1. Generalities on laser
safety 307 6.2. Laser type and classification 308 6.3. Laser risks: nature
and effects 310 6.3.1. Biological risks 310 6.3.2. Risks to the eye 312
6.3.3. Risks to the skin 314 6.3.4. Risk to hearing 315 6.3.5. Other
biological risks 315 6.4. Protections 316 6.4.1. Accident prevention 316
6.4.2. Collective protection 316 6.4.3. Individual protection 318 6.5.
Safety advice 319 6.6. Human behavior 320 Conclusion 321 Alain BOUTIER
Nomenclature 323 List of Authors 329 Index 331
Scattering by Particles 1 Fabrice ONOFRI and Séverine BARBOSA 1.1.
Introduction 1 1.2. A brief synopsis of electromagnetic theory 2 1.2.1.
Maxwell's equations 2 1.2.2. Harmonic electromagnetic plane waves 4 1.2.3.
Optical constants 9 1.2.4. Light scattering by a single particle 11 1.3.
Methods using separation of variables 16 1.3.1. Lorenz-Mie (or Mie) theory
16 1.3.2. Debye and complex angular momentum theories 26 1.4. Rayleigh
theory and the discrete dipole approximation 29 1.4.1. Rayleigh theory 29
1.4.2. Discrete dipole approximation 31 1.5. The T-matrix method 32 1.6.
Physical (or wave) optics models 34 1.6.1. Huygens-Fresnel integral 35
1.6.2. Fraunhofer diffraction theory for a particle with a circular cross
section 37 1.6.3. Airy theory of the rainbow 40 1.6.4. Marston's
physical-optics approximation 44 1.7. Geometrical optics 47 1.7.1.
Calculation of the scattering angle 48 1.7.2. Calculation of the intensity
of rays 48 1.7.3. Calculation of the phase and amplitude of rays 49 1.8.
Multiple scattering and Monte Carlo models 50 1.8.1. Scattering by an
optically diluted particle system 50 1.8.2. Multiple scattering 51 1.8.3.
Monte Carlo method 52 1.9. Conclusion 57 1.10. Bibliography 57 Chapter 2.
Optical Particle Characterization 67 Fabrice ONOFRI and Séverine BARBOSA
2.1. Introduction 67 2.2. Particles in flows 69 2.2.1. Diameter, shape and
concentration 69 2.2.2. Statistical representation of particle size data 70
2.2.3. Concentrations and fluxes 74 2.3. An attempt to classify OPC
techniques 75 2.3.1. Physical principles and measured quantities 75 2.3.2.
Nature and procedure to achieve statistics 76 2.4. Phase Doppler
interferometry (or anemometry) 77 2.4.1. Principle 77 2.4.2. Modeling the
phase-diameter relationship 81 2.4.3. Experimental setup and typical
results 87 2.4.4. Conclusion 90 2.5. Ellipsometry 91 2.6. Forward (or
"laser") diffraction 93 2.6.1. Principle 93 2.6.2. Modeling and inversion
of diffraction patterns 95 2.6.3. Typical experimental setup and results 98
2.6.4. Conclusion 100 2.7. Rainbow and near-critical-angle diffractometry
techniques 101 2.7.1. Similarities to forward diffraction 101 2.7.2.
Rainbow diffractometry 102 2.7.3. Near-critical-angle diffractometry 107
2.8. Classical shadowgraph imaging 112 2.8.1. Principle and classical setup
112 2.8.2. One-dimensional shadow Doppler technique 114 2.8.3. Calculation
of particle images using the point spread function 115 2.8.4. Conclusion
118 2.9. Out-of-focus interferometric imaging 119 2.9.1. Principle 119
2.9.2. Modeling the diameter-angular frequency relationship 120 2.9.3.
Conclusion 126 2.10. Holography of particles 128 2.10.1. Gabor holography
for holographic films 128 2.10.2. Inline digital holography 129 2.10.3.
Conclusion 131 2.11. Light extinction spectrometry 132 2.11.1. Principle
132 2.11.2. Algebraic inverse method 134 2.11.3. Experimental setup and
conclusion 136 2.12. Photon correlation spectroscopy 139 2.13.
Laser-induced fluorescence and elastic-scattering imaging ratio 141 2.13.1.
Principle 142 2.13.2. Experimental setup and results 143 2.13.3. Conclusion
144 2.14. Laser-induced incandescence 144 2.15. General conclusions 145
2.16. Bibliography 146 Chapter 3. Laser-Induced Fluorescence 159 Fabrice
LEMOINE and Frédéric GRISCH 3.1. Recall on energy quantification of
molecules 159 3.1.1. Radiative transitions 162 3.1.2. Energy level
thermo-statistics 164 3.1.3. Franck-Condon principle 164 3.1.4.
Non-radiative transitions 164 3.1.5. Line width 165 3.2. Laser-induced
fluorescence principles 168 3.2.1. Absorption kinetics 169 3.2.2.
Fluorescence signal 170 3.2.3. Fluorescence detection 173 3.2.4. Absorption
along optical path 174 3.2.5. Fluorescence measurement device 175 3.3.
Applications of laser-induced fluorescence in gases 177 3.3.1. Generalities
177 3.3.2. Diatomic molecules 178 3.3.3. Poly-Atomic molecular tracers 186
3.4. Laser-induced fluorescence in liquids 202 3.4.1. Principles and
modeling 202 3.4.2. Fluorescence reabsorption 205 3.4.3. Applications to
concentration measurement 205 3.4.4. Application to temperature measurement
210 3.5. Bibliography 218 Chapter 4. Diode Laser Absorption Spectroscopy
Techniques 223 Ajmal MOHAMED 4.1. High spectral resolution absorption
spectroscopy in fluid mechanics 223 4.2. Recap on molecular absorption 226
4.2.1. Line profile 226 4.2.2. Line strength 228 4.3. Absorption
spectroscopy bench 229 4.3.1. Emitting optics 230 4.3.2. Optical detection
234 4.3.3. Spectra processing 237 4.4. Applications in hypersonic 245
4.4.1. F4 characteristics 246 4.4.2. Setup installed at F4 248 4.4.3.
Results obtained at F4 and HEG 249 4.5. Other applications of diode laser
absorption spectroscopy 250 4.5.1. Combustion applications 250 4.5.2.
Applications to atmospheric probing 253 4.6. Other devices for diode laser
absorption spectroscopy 254 4.6.1. Multipass spectrometry 254 4.6.2.
Spectrometry in a resonant cavity 257 4.7. Perspectives and conclusion on
diode laser absorption spectroscopy 261 4.7.1. Laser source: use of
non-cryogenic diodes 262 4.7.2. Spatial resolution: use of probe in flow
262 4.7.3. Use of frequency combs 264 4.8. Bibliography 264 Chapter 5.
Nonlinear Optical Sources and Techniques for Optical Diagnostic 271 Michel
LEFEBVRE 5.1. Introduction to nonlinear optics 271 5.2. Main processes in
nonlinear optics 272 5.2.1. Propagation effects 273 5.2.2. Second- and
third-order nonlinearities 276 5.2.3. Phase matching notion 280 5.3.
Nonlinear sources for optical metrology 282 5.3.1. Sum frequency generation
and frequency doubling 283 5.3.2. Raman converters 285 5.3.3. Optical
parametric generators and oscillators 289 5.4. Nonlinear techniques for
optical diagnostic 296 5.4.1. Introduction to four-wave mixing techniques
296 5.4.2. Temperature and concentration measurements in four-wave mixing
299 5.4.3. Velocity measurements in four-wave mixing 301 5.5. Bibliography
305 Chapter 6. Laser Safety 307 Jean-Michel MOST 6.1. Generalities on laser
safety 307 6.2. Laser type and classification 308 6.3. Laser risks: nature
and effects 310 6.3.1. Biological risks 310 6.3.2. Risks to the eye 312
6.3.3. Risks to the skin 314 6.3.4. Risk to hearing 315 6.3.5. Other
biological risks 315 6.4. Protections 316 6.4.1. Accident prevention 316
6.4.2. Collective protection 316 6.4.3. Individual protection 318 6.5.
Safety advice 319 6.6. Human behavior 320 Conclusion 321 Alain BOUTIER
Nomenclature 323 List of Authors 329 Index 331