Symposium C-1
Creation of Materials by Super-Thermal Field 2025
Scope
The scope of this conference includes, but is not limited to, scientific studies on experiments, computer simulations, and data sciences related to the following topics • Interactions between quantum beams and materials in the formation of superthermal fields • Crystal growth in superthermal fields represented by a temperature gradient higher than (10,000,000 K/m) • Large thermal strain and their relaxation • Giant Marangoni effect associated with these phenomena • Creation of new materials by utilizing the super-thermal field • Microstructure and material properties of materials grown in the super-thermal field
Topics
- Interactions between quantum beams and materials in the formation of superthermal fields
- Crystal growth in superthermal fields represented by a temperature gradient higher than (10,000,000 K/m)
- Formation mechanisms and the characterization of microstructures in AM
- Effects of residual stress and compositional modulation on materials’ properties in AM
- Methods and techniques to control and optimize the microstructure in AM
- Applications and challenges of materials formed under extreme conditions in AM
- Anisotropy of highly oriented materials’ properties of materials’ crystal growth under extreme conditions in PBF
- The creation of new materials by utilizing a large temperature gradient and rapid solidification
- Influences of thermal stress on materials’ properties fabricated in additive manufacturing, and their mitigation
- Experimental studies, computational modeling, and data-driven studies relevant to the above-mentioned phenomena
Symposium Keynote
- Yuichiro KoizumiThe University of Osaka: Creation of Materials by Super-Thermal Field in Additive Manufacturing
- Digital Twin Science of Rapid Crystal Growth in Powder Bed Fusion Process
Invited Speakers
- Pan Wang, SINGAPORE INSTITUTE OF MANUFACTURING TECHNOLOGY (SIMTECH), A*STAR RESEARCH ENTIT: In Situ Alloying in Powder Bed Fusion: Accelerating Alloy Design and Microstructural Control
- Yoko Yamabe-Mitarai, The University of Tokyo: Microstructure evolution and creep performance of LPBFed near alpha, and near beta - Ti alloys
- Ken Cho, The University of Osaka: Neutron Diffraction Analysis of Internal Residual Stress in 316L Stainless Steel Fabricated by Laser Powder Bed Fusion
- Hao Chen, Tsinghua university: Ultrastrong and Tough Medium-Carbon Steels via Additive manufacturing
- Masaki Tahara, Institute of Science Tokyo: Development of β-Ti Superelastic Alloy Fabricated by Laser Powder Bed Fusion
- Shao-Pu Tsai, National Taiwan University: Sustainable 8xxx-series Al alloys manufactured by laser-powder bed fusion (L-PBF): (in-situ) TEM observation
- Chinnapat Panwisawas, Queen Mary University of London: Design-by-Additive Manufacturing: Innovative Nanocomposites to Engineer Microstructure and Site-specific Properties using Ceramic Nanoparticles
- Wentao Yan, National University of Singapore: High-Fidelity Modeling of Multi-Material Additive Manufacturing
- Akihiko Ito, Yokohama National University: Chemically Deposited Eutectics of Rare-earth-oxide-based Nanocomposite Films using Chemical Vapor Deposition under Super-Thermal Field
Organizers
- Representative
Yuichiro Koizumi - Osaka University
- Correspondence
Kazuhisa Sato - Osaka University
sato[at]uhvem.osaka-u.ac.jp
- Takayoshi NAKANO
- Osaka University
- Yoshitaka ADACHI
- Nagoya University
- Kohei MORISHITA
- Kyushu University
- Yoshiaki TODA
- National Institute for Materials Science (NIMS)
- Takuya ISHIMOTO
- University of Toyama
- Teiichi KIMURA
- Japan Fine Ceramics Center (JFCC)
- Eric A. Jägle
- Universität der Bundeswehr München(Germany)
- Albert TO
- University of Pittsburgh
