Лазерная чистка II - Кейн Дебора

PRZEDMIOTEM OFERTY JEST KOD DOSTĘPOWY DO KSIĄŻKI ELEKTRONICZNEJ (EBOOK)

KSIĄŻKA JEST DOSTĘPNA NA ZEWNĘTRZNEJ PLATFORMIE. KSIĄŻKA NIE JEST W POSTACI PLIKU.

Laser Cleaning II is the second of a series of books reporting research on the use of lasers for cleaning material surfaces and related micro-scale and nano-scale laser processing. It follows Laser Cleaning, edited by Boris Luk'yanchuk, published in 2002. The primary focus is on contaminant particle removal, nano-scale sized particles in particular, which represents a major cleaning challenge in industrial contexts and poses a broad range of research questions. The contributions provide stimulating answers to these questions, spanning the essential areas: the fundamental theoretical and experimental physics of light/particle/interface interactions, invention and development of laser cleaning techniques and diagnostics, simulations for important material and process systems, and laser cleaning and processing applications. Laser cleaning for art and cultural heritage conservation is a related, mature field of research which is also treated.

• Autorzy: Kane Deborah
• Wydawnictwo: World Scientific Publishing
• Data wydania: 2007
• Wydanie:
• Liczba stron:
• Forma publikacji: PDF (online)
• Język publikacji: angielski
• ISBN: 9789812706843

BRAK MOŻLIWOŚCI POBRANIA PLIKU. Drukowanie: OGRANICZENIE DO 2 stron. Kopiowanie: OGRANICZENIE DO 2 stron.

• CONTENTS
• List of Contributors
• Preface
• Tribute to Professor Boris Luk'yanchuk: To Mark his Contributions to Xlll Physics on the Occasion of
• Determination of the basic parameters related to light scattering by a particle on a surface
• Application of near field effects for material processing
• Optical and magneto-optical recording
• Formation of nanoclusters during laser ablation
• Highly multiplexed scanning nanoscopic imaging
• Plasmonics
• Laser ablation and plume dynamics
• Laser thermochemistry
• Friend and poet
• References
• Acknowledgements
• Chapter 1 Laser Cleaning and Surface Modifications: Applications in Nano- and Biotechnology D. Bauer
• 1. Introduction
• 2. Removal of Particulates
• 2.1. Dry Laser Cleaning (DLC)
• 2.1.1. Substrate absorption
• 2.1.2. Particulate absorption
• 2.1.3. Particulate and substrate absorption
• 2.2. Steam Laser Cleaning (SLC)
• 2.2.1. Absorbing liquidfilms
• 2.3. Wet Laser Cleaning (WLC)
• 3. Submicron- and Nanopatterning
• 4. Removal of Contamination Layers
• 4.1. Surface polishing and glazing
• 4.2. The influence of an ambient medium
• 5. Surface Modifications of PTFE, Applications in Biotechnology
• 6. Conclusions
• Acknowledgements
• References
• Chapter 2 An Overview of Experimental Research into the Laser Cleaning of Contaminants from Surfaces
• 1. An Overview of the Information in the Tables
• 2. Categories of Laser Cleaning
• 3. Deposition Techniques
• 4. Laser Cleaning Efficiency
• 5. Laser Characteristics
• 6. Analysis Methods
• 7. A Review of Laser Cleaning of Contaminants from Surfaces
• Acknowledgments
• References
• Chapter 3 Particle on a Surface: About Possible Acoustic and Plasmonics Effects in Dry Laser Cleanin
• 1. Introduction
• 2. Particle on the Surface
• 3. Acoustic Effects in Laser Cleaning
• 4. Plasmonic Effect in Laser Cleaning of Small Metal Particles
• 5. Conclusion
• Acknowledgement
• References
• Chapter 4 Axially Symmetric Focusing of Light in Dry Laser Cleaning and Nanopatterning J. Kofler and
• 1. Introduction
• 2. The Bessoid Integral
• 2.1. Definition
• 2.2. Asymptotic expressions
• 2.3. Numerical evaluation
• 2.4. Geometrical optics for the cuspoid
• 3. Relation between Geometrical and Wave Optics
• 3.1. Matching with the Bessoid integral
• 3.2. General expressions on and near the axis
• 3.3. Angular dependences and vectorial problems: Higher-order Bessoid matching
• 4. The Sphere
• 4.1. Geometrical optics solution
• 4.2. The Bessoid matching solution
• 4.3. On the axis
• 4.4. Comparison with the theory of Mie
• 5. Conclusions
• Acknowledgments
• References
• Chapter 5 Liquid-Assisted Laser Shock Cleaning for Nanoscale Particle Removal D. Jang, B. Oh and D.
• 1. Introduction
• 2. Principles of the Cleaning Method
• 2.1. Laser shock cleaning (LSC) method
• 2.2. Steam laser cleaning (SLC) method
• 2.3. Liquid-assisted laser shock cleaning (LLSC) method
• 3. Experimental
• 3.1. Sample preparation
• 3.2. Cleaning experiment
• 4. Results and Discussion
• 4.1. Combined effect of explosive vaporization and shock wave impingement
• 4.2. CuO nanoparticle cleaning
• 4.3. A1203 nanoparticle cleaning
• 5. Conclusions
• Acknowledgments
• References
• Chapter 6 UV Laser-Induced Dehydroxylation of UV Fused Silica Surfaces A. J. Fernandes, D. M. Kane,
• 1. An Introduction to the Surface Structure and Dehydroxylation of Silica Glass
• 2. Guidelines for Sample Preparation
• 2.1. Pre-treatment of samples before laser irradiation and sample storage
• 2.2. The hydrogen peroxide cleaning process
• 2.3. Laser irradiation experimental setup
• 3. Time-of-Flight Secondary Ion Mass Spectrometry (ToF-SIMS)
• 3.1. An introduction to ToF-SIMS
• 3.2. Analysis of the surface hydroxyl concentration and the effect of hydrocarbon masking
• 4. Experimental Results
• 4.1. Dehydroxylation as a function of laser pulse fluence
• 4.2. Dehydroxylation as a function of totalflueme applied
• 4.3. Dehydroxylation as a function of laserpulse number
• 4.4. Dehydroxylation as a function of laser repetition rate
• 5. Discussion
• 6. Conclusions
• Acknowledgments
• References
• Chapter 7 Removal of Silica Microspheres from Glass and Silica Substrates by Dry Laser Cleaning S. P
• 1. Introduction
• 2. Experimental Work
• 3. “Dry” Laser Cleaning Results and Discussion
• 4. High Laser Fluence Effects
• 5. Conclusions
• Acknowledgements
• References
• Chapter 8 The Effect of Pulse Shape on 3D Modeling of Laser Cleaning Fluences S. Pleasants, D. M. Ka
• 1. Introduction
• 2. Description of Mdel Used
• 3. Results and Discussion
• 4. Conclusions
• Acknowledgements
• References
• Chapter 9 Nanoparticles During Laser Cleaning of Decoration Samples of Sigismund's Chapel S. Barciko
• 1. Introduction
• 2. Experimental
• 3. Laser Cleaning of Decoration Samples of Sigismund’s Chapel
• 4. Characterisation of Nanoparticles During Laser Cleaning
• 5. Risk Assessment
• 6. Conclusion and Outlook
• Acknowledgments
• References
• Chapter 10 Femtosecond Laser Cleaning of Metallic Antique Artworks - Advantages, Limits and Economic
• 1. Introduction
• 2. Experimental Setup
• 3. Femtosecond Laser Cleaning of Bronze and Copper Objects
• 4. Economic Aspects
• 5. Practicability
• 6. Conclusion and Outlook
• Acknowledgments
• References
• Chapter 11 Ultrafast Laser Cleaning of Museum Artifacts A. V. Rode, N. R. Madsen, E. G. Gamaly, B. L
• 1. Laser Cleaning of Artworks
• 2. Experiments with PS-Pulse Laser Cleaning
• 2.1. Laser cleaning of metal samples
• 2.2. Summary of the experiments
• 3. Application of Laser Cleaning Technique to the Museum Artefacts
• 3.1. Traditional art collectables
• 3.2. Conservation techniques for modern collections
• 3.3. New challenges in conservation and restoration of modern collections at the Australian War Memo
• 3.3.1. Removal of overlying paint, wax or varnish from original paint
• 3.3.2. Removal ofpaint, oil or dirtfrornplastics such as Perspex
• 3.3.3. Removal ofpaint, polish residues and dirt from organic materials with complex, easily damaged
• 3.3.4. Cleaning ofphotographic emulsions
• 3.3.5. Removal ofcorrosion
• 3.3.6. Removal of radioactive materialfiom contaminated objects
• 4. Conclusion
• References
• Chapter 12 Laser Cleaning of Entrance Window During Ultra-Fast Pulsed Laser Deposition N. R. Madsen,
• 1. Introduction
• 2. Experimental
• 2.1. Experimental setup
• 2.2. Laser scanning system
• 2.3. Irradiation thresholds
• 2.4. Cleaning rates
• 3. Results and Discussion
• 4. Conclusion
• Acknowledgments
• References
• Chapter 13 Surface Cleaning of Optical Materials Using Novel VUV Sources D. M. Kane, D. Hirschausen,
• 1. Introduction
• 2. Wax and Thermopolymer Removal - Experiment
• 2.1 Sample preparation -glass and silica substrates
• 2.1.1 ParafJin wax and thermopolymer CB 555 particles on parafin and silica substrates
• 2.1.2 Thermopolymer CB 509 on glass and silica substrates
• 2.2 W V DBD removal of wax and thermopolymer - Method
• 2.3 Results and discussion of wax and thermopolymer removal from glass and silica
• 3. HydrocarbonAWoisture Removal from Glass and Polymer Surfaces
• 3.1 Experiment
• 3.2 Hydrocarbodmoisture removal - Results and discussion
• 4. Conclusions
• Acknowledgments
• References
• Chapter 14 Micro- and Nano-Machining with Ultrashort Laser Pulses: From Basic Science to The Real Wo
• 1. Introduction
• 2. Basic Properties of Ultrashort-Pulse Laser Machining
• 2.1. Ultra-short pulses yield high precision
• 2.2. Ultrashort pulses are versatile
• 2.3. Point 1: Shortpulses mean large bandwidth
• 2.4. Point 2: Short pulses mean large intensities and possibly non-linear propagation effects
• 2.5. Point 3: Diffractive optics stretches the pulse
• 2.6. Point 4: Throughput is fundamentally limited
• 2.7. Point 5: Thermal effects during drilling of metals
• 3. Optimizing Ultrashort-Pulse Laser Machining
• 3.1. Challenge 1: Reproducibility
• 3.2. Challenge 2: Deep drilling of metals
• 3.3. Challenge 3: “Non-constant” ablation rates
• 3.4. Challenge 4: Optimizing throughput by parallel processing
• 4. Conclusion
• Acknowledgments
• References
• Chapter 15 Optical Surface Profilomctry of Low Reflectance Materials - Evaluation as a Laser Process
• 1. Introduction
• 2. Surface Damage Sites Resulting from High Laser Pulse Energy Irradiation of a Silica Microsphere o
• 2.1 Experiment
• 2.2 Results & discussion
• 3. Optical Surface Profiler Investigation of Transparent Silica Microspheres on a Transparent Substr
• 3.1 Issues
• 3.2 Experiments, results and discussion
• 3.2.1 Silica microsphere on a microscope slide
• 3.2.2 Metal coated “silica microsphere on a microscope slide )’ samples
• 3.2.3 Silica microsphere on metal coated microscope slide
• 3.2.4 Silica microsphere on a microscope slide with scan length set to avoid the slide surface
• 4. Conclusion
• Acknowledgements
• References

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