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010   $a9786611006273
010   $a1-4294-7843-8
010   $a0-08-049280-0
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100   $a20041130d2005      uy             0
101 0 $aeng
135   $aurcn|||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aLaser processing of engineering materials$b[electronic resource] $eprinciples, procedure and industrial application /$fJohn C. Ion
210   $aAmsterdam $cElsevier/Butterworth-Heinemann$d2005
215   $a1 online resource (589 p.)
300   $aDescription based upon print version of record.
311   $a0-7506-6079-1 
320   $aIncludes bibliographical references and index.
327   $aCOVER; LASER PROCESSING OF ENGINEERING MATERIALS; CONTENTS; FOREWORD; PREFACE; ACKNOWLEDGEMENTS; PROLOGUE; 1 INTRODUCTION; INTRODUCTION AND SYNOPSIS; THE LASER - AN INNOVATIVE MACHINE TOOL; LASERS IN MATERIAL PROCESSING; IN THE HOME; IN HEALTHCARE; IN MANUFACTURING; IN THE ARTS; SUMMARY AND CONCLUSIONS; 2 EVOLUTION OF LASER MATERIAL PROCESSING; INTRODUCTION AND SYNOPSIS; FOUNDATIONS; THE NATURE OF LIGHT AND MATTER; DEVELOPMENT OF THE MASER; PRINCIPLES OF THE LASER; THE 1960's; THE FIRST LASER; THE LASER RUSH; THE FIRST PROCESSES; THE 1970's; LASERS; SYSTEMS AND PROCESSES; THE 1980's; LASERS
327   $aFLEXIBLE MANUFACTURING SYSTEMSTHE 1990's; LASERS; TURNKEY PROCESSING SYSTEMS; THE NEW MILLENNIUM; LASERS; PROCESSES; SUMMARY AND CONCLUSIONS; FURTHER READING; BIBLIOGRAPHY; 3 LASERS; INTRODUCTION AND SYNOPSIS; GENERATION OF LASER LIGHT; ENERGY LEVELS; Energy Level Notations; Distribution of Energy; Population Inversion; EXCITATION; Energy Level Transitions; LIGHT AMPLIFICATION; OUTPUT; Efficiency; CONSTRUCTION AND OPERATION OF COMMERCIAL LASERS; Active Media; Gases; Liquids; Insulating Solids; Semiconductors; Excitation; Electrical Pumping; Optical Pumping; Chemical Pumping; Optical Cavity
327   $aStability of the Optical Cavity Resonator Support; Output Devices; OUTPUT; Spatial Mode; Cylindrical Symmetry; Rectangular Symmetry; Fresnel Number; Temporal Mode; Q-switching; Cavity Dumping; Mode Locking; Chirping; Frequency Multiplication; Raman Effect; Propagation; Waist; Focused Spot Size; Rayleigh Length; Radius of Curvature; Fields; Divergence; Quality; Bandwidth; Coherence; Brightness; Intensity; Polarization; LASERS FOR MATERIAL PROCESSING; ATOMS; Helium-Neon; Iodine; Free Electron; Xenon; MOLECULES; Carbon Dioxide; Sealed; Transversely Excited Atmospheric Pressure; Slow Axial Flow
327   $aFast Axial Flow Transverse Flow; Gas Dynamic; Carbon Monoxide; Hydrogen Fluoride; Deuterium Fluoride; Hydrogen Chloride; Nitrogen; Organic; IONS; Argon; Krypton; Argon-Krypton; Xenon; Copper Vapour; Gold Vapour; Helium-Cadmium; Helium-Selenium; X-ray; EXCIMERS; Argon Fluoride; Krypton Fluoride; Xenon Chloride; Xenon Fluoride; Fluorine; Xenon; Xenon Bromide; LIQUIDS; Rhodamine; Coumarin; SOLIDS; Nd:YAG; Nd:glass; Ruby; Alexandrite; Ti: sapphire; Diode-pumped Solid State; Nd:YAG; Er:YAG; Er:YLF; Ho:YAG and Ho:YLF; Yb:YAG; Nd:YLF; Nd:YAP; Nd:GGG; Tm:YAG; Colour Centre; SEMICONDUCTORS; GaAs; InGaAs
327   $aInGaAlAsGaN; Lead Salt; SUMMARY AND CONCLUSIONS; FURTHER READING; 4 SYSTEMS FOR MATERIAL PROCESSING; INTRODUCTION AND SYNOPSIS; OPTICS; OPTICAL TERMINOLOGY; Focal Length; Focal Number; Beam Diameter at Focus; Depth of Focus; TRANSMISSIVE OPTICS; Materials; Coatings; Beam Splitters; LENS PARAMETERS; Plano-convex Lens; Positive Meniscus Lens; Aspheric Lens; Polarizers; Beam Collimators; Axicon Lens; Beam Integrator; Fibreoptics; Line Focus; Aberrations; REFLECTIVE OPTICS; Materials; Coatings; Beam Turning Mirrors; Beam Splitting Mirrors; Spherical Mirrors; Paraboloidal Mirrors
327   $aDeformable Mirrors
330   $aThe complete guide to understanding and using lasers in material processing! Lasers are now an integral part of modern society, providing extraordinary opportunities for innovation in an ever-widening range of material processing and manufacturing applications. The study of laser material processing is a core element of many materials and manufacturing courses at undergraduate and postgraduate level. As a consequence, there is now a vast amount of research on the theory and application of lasers to be absorbed by students, industrial researchers, practising engineers and production
606   $aLasers$xIndustrial applications
606   $aPhotonics
615  0$aLasers$xIndustrial applications.
615  0$aPhotonics.
676   $a621.366
700   $aIon$b John C$0498674
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910784454703321
996   $aLaser processing of engineering materials$9734305
997   $aUNINA