Bringing together contributions from leading experts in the field, this book reviews laser processing concepts that allow the structuring of material beyond optical limits, and methods that facilitate direct observation of the underlying mechanisms by exploring direct structuring and self-organization phenomena. The capacity to nanostructure material using ultrafast lasers lays the groundwork for the next generation of flexible and precise material processing tools. Rapid access to scales of 100 nm and below in two and three dimensions becomes a factor of paramount importance to engineer materials and to design innovative functions. To reflect the dynamic nature of the field at all levels from basic science to applications, the book is divided into three parts, Fundamental Processes, Concepts of Nanostructuring, and Applications, each of which is comprehensively covered. This book will be a useful resource for graduate students and researchers in laser processing, materials engineering, and nanoscience.
Recenzijas
The editors of this book have succeeded admirably in bringing together the best work on materials processing at the nanometer scale. The sheer number of 1,245pages, organized in three volumes and illustrated with 586 figures, shows how comprehensive it has become. It is the right book at the right time . This book is set to become the new standard reference for this field. (Andreas Thoss, optica-opn.org, November 2, 2023)
Part I: Fundamental Processes in Laser 2D/3D Nanostructuring.
Chapter 1: Insights into laser-matter interaction from inside: wealth of processes, multiplicity of mechanisms and possible roadmaps for energy localization.
Chapter 2: The atomistic perspective of nanoscale laser ablation.
Chapter 3: Ultrafast quantum processes at the nanoscale: insights from modelling.
Chapter 4: The universality of self-organisation; where is the limit? A way forward to an atom printer?.
Chapter 5: How light drives material periodic patterns down to the nanoscale.
Chapter 6: In-situ observation of the formation of laser-induced periodic surface structures with extreme spatial and temporal resolution.
Chapter 7: Probing matter by light.
Chapter 8: Probing light by matter: Implications of complex illumination on ultrafast nanostructuring.
Chapter 9: Imaging Dynamics of Femtosecond Laser Induced Surface Nanostructuring.- Part II: Concepts of Extreme Nanostructuring.
Chapter 10: Macro-scale microfabrication enabled by nano-scale morphological control of laser internal modification.
Chapter 11: Optical nanostructuring by near-field laser ablation.
Chapter 12: Nanoscale plasmonic printing.
Chapter 13: Search for high-pressure silicon phases: Reaching the extreme conditions with high-intensity laser irradiation.
Chapter 14: Periodic surface structures by laser interference ablation.
Chapter 15: Spatial beam shaping with a liquid-crystal spatial light modulator for surface micro- and nanoprocessing.
Chapter 16: Non-standard light for ultrafast laser micro- and nano- structuring.
Chapter 17: Controlled nanostructuring of transparent matter with temporal Airy pulses.
Chapter 18: Ultraprecise surface processing by etching with laser-induced plasma.
Chapter 19: Nanostructuring by photochemistry: Laser induced type A modification.
Chapter 20: Subtractive 3D laser nanolithography of crystals by giant wet-chemical etching selectivity.
Chapter 21: Ultrafast meets ultrasmall: whereare the limits of ultrafast waveguide writing?.
Chapter 22: Multi-photon 3D lithography and calcination for sub-100-nm additive manufacturing of inorganics.- Part III: Functions and Applications.
Chapter 23: Creation of material functions by nanostructuring.
Chapter 24: Role of surface chemistry on wettability of laser machined metallic surfaces.
Chapter 25: Ultrafast laser biomimetic micro/nanostructuring.
Chapter 26: Ultrarapid industrial large area processing using laser interference patterning methods.
Chapter 27: Internal structuring of semiconductors with ultrafast lasers: opening a route to three-dimensional silicon photonics.
Chapter 28: Nanoscale sampling of optical signals, application to high resolution spectroscopy.
Chapter 29: Ultrafast laser volume nanostructuring of transparent materials; from nanophotonics to nanomechanics.
Chapter 30: Nanofluidics fabricated by 3D femtosecond laser processing.
Chapter 31: Laser structuring for biomedical applications.
Chapter 32: Laser nanostructuring for SERS applications.
Chapter 33: Laser micro- and nanostructuring for refractive eye surgery.
Razvan Stoian graduated in 1996 from the Bucharest University, Romania, and received his doctoral degree in 2000 from the Free University, Berlin, Germany. He was with the Ultrafast Laser Material-Processing Group at the Max-Born Institute, Berlin between 1997 and 2004, and joined the Centre Nationale de la Recherche Scientifique France in 2004 where he is now Research Director. He is leading the Laser-Matter Interaction group at Laboratoire Hubert Curien in St. Etienne, France. He is equally scientific director of Manutech-USD, a technological platform for advanced laser processing for industry. His research interests include lasermatter interactions, ultrafast phenomena, beam engineering, and ultrafast laser material processing.
Jörn Bonse graduated from the University of Hannover in 1996, and received a doctoral degree in 2001 from the Technical University, Berlin, Germany. He was with the Laser Zentrum Hannover (LZH), the Spanish National Research Council (CSIC) in Madrid, 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, surface functionalization, and laser-induced periodic nanostructures.
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