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Meeting MS&T22: Materials Science & Technology
Symposium Additive Manufacturing of Ceramic-based Materials: Process Development, Materials, Process Optimization and Applications
Sponsorship ACerS Basic Science Division
ACerS Engineering Ceramics Division
ACerS Manufacturing Division
Organizer(s) Lei Chen, University of Michigan-Dearborn
Xuan Song, University of Iowa
Xiangyang Dong, Missouri University of Science and Technology
Yiquan Wu, Alfred University
Paolo Colombo, University of Padova
Rajendra K. Bordia, Clemson University
Long-Qing Chen, Pennsylvania State University
Scope The wide-use of advanced ceramic-based materials depends on the availability of industrial processing routes to fabricate parts with required geometries. However, it is still challenging for current manufacturing methods to produce complex shaped ceramic parts with the desired microstructures and properties. Additive Manufacturing (AM) or 3D printing is a fast-growing technique for fabricating parts layer-by-layer directly from 3D digital models. AM has tremendous potential for producing high-value, complex, individually customized parts. While AM technologies for ceramics have been extensively explored in the past decade, additively shaping ceramic materials with high performance and high reliability remains challenging, due to their inherent brittleness and stringent processing requirements (feedstock and/or sintering). As more technological progress continues in the field, it can be expected that AM technologies will have an extraordinary impact on the industrial production of ceramic components and will open up new possibilities for ceramics uses and markets.

This symposium will highlight recent advances in additive manufacturing of ceramic-based materials. The topics of presentations are sought to include but not limited to:

1. Hybridized processes for ceramic-based materials based on established technologies (Sheet Lamination, Powder Bed Fusion, Directed Energy Deposition, Material Jetting, Binder Jetting, Binder Jetting, Material Extrusion), and novel approaches;

2.Computational and experimental investigations of process-microstructure-property relations, including but not limited to multiscale multi-physics computational modelling, and in-situ and ex-situ characterization of grain structures, porosity, surface roughness, structural and functional properties for AM-fabricated ceramics and ceramics composites;

3. Data-driven process optimization and quality control of AM ceramic-based components, e.g., based on surrogate models, uncertainty quantification, machine learning and deep learning technologies;

4. Novel applications of AM ceramic-based components.

Abstracts Due 05/15/2022
Proceedings Plan Undecided

A-13: Evaluation of Reliability of Using Combined Rheological Methods for the Development of Ceramic Materials for 3D Printing
A-14: Nanomechanical Characterization of 3D Printed Ceramics
A-15: Rheological Study of 3D Printable All-inorganic Thermoelectric Inks for Direct Writing of Micro-thermoelectric Generator
A Study of Lithography-Based Additive Manufacturing of Ceria Ceramics
Additive Manufacturing of Alumina Toughened Zirconia and Zirconia Toughened Alumina
Additive Manufacturing of Mullite Ceramic by Digital Light Processing
Advanced Manufacturing of Controlled SOFC Electrolyte and Electrode Microstructures through Aerosol Deposition
Bonding Mechanisms in Indirect Selective Laser Sintering
Brittle Particle Cold Spray Technology
Ceramic 3D Printing for Investment Casting
Ceramic Additive Manufacturing for Innovative Zirconia-based Material
Direct Ink Writing of Nanoscale Feature Ceramics via Preceramic Polymer-block Copolymer Inks
Effects of Bimodal Particle Size Distribution on Mechanical and Thermal Properties of Densified SiC-Si Composites from Binder Jetting
Exploration of the Underlying Space in Microscopic Images via Deep Learning for Additively Manufactured Piezoceramics
Fabrication of Powder Components with Cooling Channels by Spark Plasma Sintering and Additive Manufacturing
Influence of Laser Processing Parameters on Thermoelectric and Microstructural Properties of Bi2Te3
Mass Customization, Moving Forwards with Additive Manufacturing
Micro-Cold Spray: Effect of Particle Impact Velocity on SiC Film Morphology
Modeling and Monitoring of Thermal Accumulation During Laser Powder Bed Fusion of Cemented Carbides
Multi-material Printing of Reaction Bonded Carbides by Robocasting
Phase-field Modeling of Co-Sintering of Ceramic Electrolyte/Electrode for All Solid-State Li-ion Batteries
Production of 3D Printed Electrodes for Batteries
Rapid Three-dimensional Printing of High-resolution Piezoelectric Structures Using Micro-CLIP
SLA-based Additive Manufacturing of 3D Structures with Surface Activated Silicone Carbide-polymer Composite
Transparent Alumina Fabricated by Energy Efficient Spark Plasma Sintering

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