Introduction to Surface Engineering and Functionally Engineered Materials

Peter Martin worked at Battelle, Pacific Northwest Laboratory (BNW) for over 29 years where he currently holds an Emeritus Laboratory Fellow appointment, and specializes in developing thin film coatings for energy, biomedical, space and defense applications. He pioneered the use of reactive magnetron sputtering technology to fabricate novel and advanced optical coating materials and specializes in large area optical and thin film coating development. He has also led development of high performance large area ground-based and space-based laser mirrors for DOD applications. Dr. Martin has written over 400 technical publications. He has won three R&D 100 Awards for his work in microfabrication and barrier coatings for flat panel displays, has two FLC awards, was awarded Battelle Technology of the Year (2003) for his work with the photolytic artificial lung, and voted Distinguished Inventor and PNNL 2005 Inventor of the Year. He has 26 US patents and numerous foreign and pending patents. He also teaches short courses on smart materials and energy materials and applications.

1.0 Properties of Solid Surfaces. 1.1 Introduction. 1.2 Tribological Properties of Solid Surfaces. 1.3 Optical Properties of Solid Surfaces. 1.4 Electrical and Opto-electronic Properties of Solid Surfaces. 1.5 Corrosion of Solid Surfaces. 2.0 Thin Film Deposition Processes. 2.1 Physical Vapor Deposition. 2.2 Chemical Vapor Deposition. 2.3 Pulsed Laser Deposition. 2.4 Hybrid Deposition Processes. 3.0 Thin Film Structures and Defects. 3.1 Thin Film Nucleation and Growth. 3.2 Structure of Thin Films. 3.3 Thin Film Structure Zone Models. 4. Thin Film Tribological Materials. 4.1 Wear Resistant Thin Film Materials. 4.2 Ultrifunctional Nanostructured, Nanolaminate and Nanocomposite Triboligical Materials. 5. Optical Thin Films and Composites. 5.1 Optical Properties at an Interface. 5.2 Single Layer Optical Coatings. 5.3 Multilayer Thin Film Optical Coatings. 5.4 Color and Chromaticity in Thin Films. 5.5 Decorative and Architectural Coatings. 6.0 Fabrication Processes for Electrical and Electro-Optical Thin Films. 6.1 Plasma Processing: Introduction. 6.2 Etching Processes. 6.3 Wet Chemical Etching. 6.4 Metallization. 6.5 Photolithography. 6.6 Deposition Process for Piezoelectric and Ferroelectric Thin Films. 6.7 Deposition Processes for Semiconductor Thin Films. 7.0 Functionally Engineered Materials. 7.1 Energy Band Structure of Solids. 7.2 Low Dimensional Structures. 7.3 Energy Band Engineering. 7.4 Artificially Structured and Sculpted Micro and NanoStructures. 8.0 Multifunctional Surface Engineering Applications. 8.1 Thin Film Photovoltaics. 8.2 Transparent Conductive Oxide Thin Films. 8.3 Electrochromic and Thermochromic Coatings. 8.4 Thin Film Permeation barriers. 8.5 Photocatalytic Thin Films and Low Dimensional Structures. 8.6 Frequency selective surfaces. 9.0 Looking into the Future: Bio-Inspired Materials and Surfaces. 9.1 Functional Biomaterials. 9.2 Functional Biomaterials: Self Cleaning Biological Materials. 9.3 Functional Biomaterials: Self Healing Biological Materials. 9.4 Self Assembled and Composite Nanostructures. 9.5 Introduction to Biophotonics. 9.6 Advanced Biophotonics Applications.