Vakuum-Plasma-Technologien

Editors: Prof. Dr. Gerhard Blasek and Prof. Dr. Günter Bräuer

With contributions from the following authors:
Prof. Dr. Karlheinz Blankenbach, Dr. Ronny Brandenburg, Dr. Volker Bucher, Dr. Bernhard Cord, Dr. Jörg Ehlbeck, Dr. Elke Erhart, Dr. Werner Fleischer, Prof. Dr. Jörg Friedrich, Prof. Dr. Frank Gräbner, Dr. Werner Grimm, Dr. Reiner Grün, Dr. Heiner Grünwald, Andreas Holländer, Dr Steffen Howitz, Dr Tomas Jung, Peter Kästner, Prof. Dr Holger Kersten, Udo Krohmann, Dr Per Krüger, Prof. Dr Horst-Christian Langowski, Wolfram Maass, Dr Mirko Nitschke, Berthold Ocker, Dr Andreas Ohl, Davorin Pavic, Prof. Dr. Hans-Ulrich Poll, Prof. Dr. Hans K. Pulker, Ekkehardt Reinhold, Dr. Jana Reinhold, Hartmut Rohrmann, Dr. Dietmar Roth, Prof. Dr. Silvia Roth, Dr. Hermann Schlemm, Burkhard Scholz, Dr. Karsten Schröder, Prof. Dr. Bernd Schultrich, Dr. Manfred Stieber, Dr. Roland Thielsch, Dr Michael Vergöhl, Prof. Dr Achim von Keudell, Dr Thomas von Woedtke, Prof. Dr Klaus Wandel, Prof. Dr Klaus-Dieter Weltmann, Dr Christian Wenzel, Prof. Dr Klaus Wetzig, Rüdiger Wilberg, Rolf Winkler, Dr Olaf Zywitzki.

Vacuum and plasma have found their way into almost all technical disciplines and contribute significantly to their scientific and technical progress. The coating of solids in a vacuum and the modification of near-surface areas using vacuum and plasma processes create products with new utility values. This applies in particular to toolmaking and all areas of mechanical and automotive engineering, construction, glass, ceramics and plastics processing and surface finishing, electronics, as well as food, biotechnology and medical technology. Vacuum and plasma processes enable resource-saving production and give products completely new properties such as extreme hardness, reduced mechanical and chemical wear, better biocompatibility, and new optical, electrical, magnetic and aesthetic properties. It should be noted that the potential of vacuum and plasma technology is far from being exhausted.

Summary Part I
1. Fundamentals of vacuum and plasma technology
1.1 Fundamentals of vacuum technology
1.2 Fundamentals of plasma technology
1.3 Fundamentals of vacuum coating and surface modification
1.4 Fundamentals of optical coatings
1.5 Surface and thin film characterisation
2 Processes
2.1 Coating by evaporation
2.2 Coating production by sputtering
2.3 Plasma-assisted chemical vapour deposition
2.4 Plasma polymerisation
2.5 Etching using plasmas
2.6 Modification and coating of polymer surfaces

Summary Part II
3 Vacuum and plasma technology applications
3.1 Optical coatings
3.2 Architectural glass coating
3.3 Thermal insulation glazing in automotive engineering
3.4 Large-area industrial microwave plasma coating for photovoltaics
3.5 Thermal solar collectors
3.6 Photocatalytic coatings
3.7 Coating systems for data storage and their industrial production
3.8 Flat screens and displays
3.9 Friction and wear-reducing coatings
3.10 Plasma-assisted diffusion processes for the surface treatment of metals
3.11 Coating of plastic beverage bottles
3.12 Decorative vacuum coating
3.13 Manufacture of components for microfluidics
3.14 Low-pressure plasma processes in assembly and joining technology
3.15 Fine cleaning of surfaces with low-pressure plasmas
3.16 Plasma processes for influencing the biocompatibility of surfaces
3.17 Antimicrobial surfaces through plasma treatment
3. 18 Plasma treatment of textiles and fibres
3.19 Coating and functionalisation of powders
3.20 Coatings for ensuring the electromagnetic compatibility of electronic devices
4 Vacuum and plasma-related technologies and sustainability
4.1 Sustainability as a social necessity
4. 2 Sustainability criteria and management
4.3 Sustainability aspects of vacuum and plasma-related production processes
4.4 Sustainability management for vacuum and plasma technology
4.5 Sustainability assessment of products manufactured using vacuum and plasma technology

Index with more than 2000 references

Table of contents