Reflecting the rapid development of laser technology, this book explores the scaling of laser processing with a focus on ultrafast laser technology, surface engineering, and related applications.
The performance scaling of ultrashort pulse durations, in terms of average output power and repetition frequency of emitted laser pulses, has increased exponentially over the past few decades. Transferring these advancements into laser material processing technology has become a major contributor to the rapid development of laser technology. This book addresses the latest innovations in laser technologies that can increase processing rates and yield while maintaining the high machining precision of ultrashort pulses and avoiding the accumulation of residual heat or reduction of material removal efficiency.
Effectively covering all domains of scaling of laser material processing, this book is divided into three parts: Fundamentals, Concepts and Technologies, and Processes and Applications. Written by expert authors, this book serves as an essential resource for researchers looking to develop a thorough understanding of the significant contributions of ultrafast laser technology in both current and future laser technology landscapes around the world.
1 Light in Slices: How to Enable Precise Laser Processing?.- 2 Trend of
an Average Laser Power Scaling of Ultrashort Pulses.- 3 Laser Surface
Structuring on the Macro-, Micro-, and Nanoscale.- 4 Smart Laser Processing
Strategies.- 5 The Efficiency of Laser Processing.- 6 How Does Incubation
Affect Laser Material Processing?.- 7 Ultrashort Pulse Laser Processing: From
Science to Industry.- 8 Laser Interference Patterning: Past, Present, and
Future.- 9 Laser-Induced Periodic Surface Structures LIPSS.- 10 Universal
Numerical Simulation Model for Laser Material Processing.- 11 X-Ray Hazards
in Ultrashort Pulse Laser Materials Processing.- 12 How to Select the Right
Optics.- 13 Ultrafast Optical Probing of Laser Processing.- 14 Scaling the
Wavelength to Optimize Ultrafast Laser Processing of Band-Gap Materials.- 15
Multibeam Concepts for Laser Processing.- 16 Burst Processing of Metals Using
Ultrashort Laser Pulses.- 17 Burst Processing of Band-Gap Materials Using
Ultrashort Laser Pulses.- 18 Ultrafast Laser Micro- and Nano-processing of
Cylindrical Objects.- 19 Enhancing Laser Surface Texturing through Advanced
Machine Learning Techniques.- 20 Laser Processing Rates: The Race Towards the
Square Meter per Second.- 21 Laser Based Additive Manufacturing: Processing,
Materials and Trends.- 22 Laser-processed Biomimetic Surfaces for Functional
Applications.- 23 Wettability of Metal Surfaces after Laser Processing.- 24
Micro Perforation Cutting of Glass.- 25 Accuracy in Three-Dimensional
Nanofabrication Using Two-photon Polymerization.- 26 The Roadmap of New
Capabilities of High-Intensity Lasers in Material Design and Manipulation.-
27 Surface Functionalization with Lasers: from Nanostructures to
Applications.- 28 The European Footprint of Laser Processing.- 29 The
American Footprint Of Laser Processing.- 30 The Asian Footprint of Ultrafast
Laser Processing.- 31 Laser Welding: How Thick Can We Go?.- 32 Strategies for
Fast Ultrashort-Pulsed Laser Micro-Structuring of Large Technical Rollers in
Printing and Embossing Applications.- 33 Laser Processing for Energy
Applications.- 34 Applications of Lasers for the Generation of Decorative and
Artistic Features.- 35 Applications of Lasers for the Generation of Security
Features.- 36 Laser Applications in Electronics Industry.- 37 UV Laser
Processes for Flat Panel Displays.- 38 Technology Transfer: From the
Laboratory to Production - Industrially Scalable Laser Scan Method for
Ceramics and Glass.- 39 Laser Drilling Applications in Aviation.- 40 Laser
Innovations for Space: System Development and Utilization.- 41 High Density
Data Storage with Lasers: The Stairway to Eternity.
Jörn Bonse graduated from the University of Hannover in 1996 and received a doctoral degree in physics in 2001 from the Technical University, Berlin, Germany. He was with the Laser Zentrum Hannover (LZH), the Spanish National Research Council (CSIC) in Madrid, the University of Siegen, and the Max-Born-Institute (MBI) in Berlin. He was subsequently appointed as a Senior Laser Application Specialist at Newports Spectra-Physics Lasers Division in Stahnsdorf, Germany. Currently, he is a tenured scientist at the German Federal Institute for Materials Research and Testing (BAM) in Berlin. His research interests include the fundamentals and applications of lasermatter interaction, laser micro- and nanoprocessing, surface functionalization, and laser technology.
Andrés Fabián Lasagni received the M.Sc. degree in chemical engineering from National Comahue University, Argentina, in 2002 and the Ph.D. degree in materials science from Saarland University, Germany in 2006. From 2007 to 2008, he was a Research Scientist and Alexander von Humboldt Fellow with the Georgia Institute of Technology, USA. From 2008 to 2017, he was a Group Leader with the Fraunhofer Institute for Material and Beam Technology (IWS) in Dresden, Germany. Since 2012, he is Professor at the Institute of Manufacturing, at the Technische Universität Dresden, and since 2017 Director of the Center for Advanced Micro-Photonics (CAMP), in cooperation with Fraunhofer IWS. His research interests include the development of functionalized surfaces using laser-based fabrication methods, optical devices for high-throughput laser texturing and in-line monitoring systems.
