SYMPOSIUM 2: Advanced Ceramic Coatings for Structural, Environmental, and Functional Applications
High-performance ceramic coating systems are key to current and future technologies. Ceramic coatings extend lifetime or even enable operation of engineering materials in harsh environments. Advanced gas turbine engine components made of ceramic matrix composites, intermetallics, or superalloys promise higher energy efficiency due to increasing operation temperatures. Advanced thermal and environmental barrier coatings (T/EBC) are mandatory to protect components against the synergistic attack of heat, combustion atmosphere, and inorganic, CMAS-type aerosols. Oxidation protection provided by ceramic coatings is crucial for non-oxide, ultra-high temperature ceramics and composites to be used in reusable spacecraft or hypersonic vehicles. Protection of metal components against oxidation, corrosion, erosion, and wear by innovative ceramic coatings is also a central building block for many other technologies. Functional ceramic coatings are essential for many renewable energy applications.
The symposium addresses R&I in the fields of processing, microstructure, performance, and durability of advanced ceramic coatings. New materials, innovative processing technologies, advanced characterization methods, and modeling are particularly emphasized. Material scientists and engineers from around the world are invited to present and discuss cutting-edge ceramic coating science and technology.
Proposed Topics
- Thermal and environmental barrier coatings for CMC, intermetallics, and alloys
- CMAS-type degradation of T/EBC: Fundamentals, modeling, and mitigation strategies
- Ceramic coatings for protection against oxidation, corrosion, erosion, and wear
- Ceramic coatings for renewable energy applications
- Processing of ceramic coatings (thermal spraying, PVD, CVD, aerosol-, polymer-, and powder-deposition and sintering)
- Microstructure-property relationships
- Advanced destructive and non-destructive characterization methods
- Modeling and simulation
- New coating materials – MAX phases, high-entropy phases, etc.
Symposium Organizers
- Peter Mechnich, German Aerospace Center (DLR), Germany
- Douglas E. Wolfe, The Pennsylvania State University, USA
- Jie Zhang, Institute of Metal Research, CAS, China
- Bryan Harder, NASA Glenn Research Center, USA
- Elizabeth Opila, University of Virginia, USA
- Ravisankar Naraparaju, German Aerospace Center (DLR), Germany
- Nadia Rohbeck, Pratt and Whitney, USA
- Kuiying Chen, NRC Ottawa, Canada
- Kang N. Lee, NASA Glenn Research Center, USA
- Eric H. Jordan, University of Connecticut, USA
- Robert Vaßen, Forschungszentrum Jülich, Germany
- Julin Wan, GE Global Research, USA
- Satoshi Kitaoka, Japan Fine Ceramics Center, Japan
- Byung-Koog Jang, Kyushu University, Japan
- David Poerschke, University of Minnesota, USA
- Ping Xiao, University of Manchester, UK
- Rodney W. Trice, Purdue University, USA
- Yutaka Kagawa, The University of Tokyo, Japan
Points of Contact
- Peter Mechnich: mechnich@dlr.de
- Doug Wolfe: dew125@psu.edu
- Jie Zhang: jiezhang@imr.ac.cn