Area
G. EDUCATION, DISSEMINATION, STRATEGY, AND TECHNOLOGY TRANSFER
Prof. Dr. Faith Nightingale
Queen Mary, University of London
Dr. David Mercier
Ansys
G1 – Interdisciplinary Materials Education
Scope
The aim of this area is to explore how materials education is being developed from an interdisciplinary approach with other science and engineering subjects, education and professional skills. Focusing on pedagogy, higher education and industry, this symposia looks at the development of materials education to meet the needs to students in higher education.
Description
Materials education is developing to better serve graduates and therefore industry and further higher education. In order to meet the needs of all stakeholders, an interdisciplinary approach needs to be taken. Engineering itself is not a one discipline form of education; it crosses different disciplinary boundaries. Therefore, it is important to instead consider engineering education as a concept, encompassing science, engineering and education as the core disciplines. Within materials education, it is not only the curriculum that needs to be considered, but assessment, pedagogy, professional skills, new directions in education and educators. In this symposium, talks can be given in any of the areas listed below.
Targeted topics
List of topics and subtopics:
- Interdisciplinary materials education
- Professional skills in materials education
- Language and materials education
- AI in materials education
- Educational technology
- Pedagogy in materials education
- Teacher education
- Industry and materials education
- Higher education in materials
- Assessing interdisciplinary materials education
- Materials education curriculum
OrganizerS
Dr. Faith Nightingale
QMUL (UK)
Dr. Christina Chin
University of Nottingham (UK)
Dr. Jennifer Bennagoun
Fuel Medical Group (US)
G2 – Disseminating materials research and strategizing new developments in materials education
Scope
The aim of this area is to explore how to disseminate materials research and devise strategies to implement these developments. How can policy be changed to better materials education via scholarship and research.
Description
Ensuring quality research is accessible is key to developing materials research. Additionally, being inclusive in dissemination is important for early careers researchers to be given a platform for their own careers’ development.
Strategic developments to meet the needs of higher education, industry and the workplace is also key to create the next generation of materials engineers and scientists. Therefore, using research to create new ways of thinking and developing specific strategies is key.
Targeted topics
List of topics and subtopics:
- Publication opportunities
- Developing early careers
- Inclusive materials research
- Strategic developments in materials engineering
- Scholarship in materials science
OrganizerS
Dr. Dan Parvez
Lightning Machines/ IOM3 (UK)
Prof. Nuria Salan
Universidad Politécnica de Cataluña (ES)
Scope
This Symposium aims to explore how material informatics can accelerate the complex journey of bringing innovative materials from laboratory breakthroughs to market-ready solutions, uniting researchers, industry leaders, and technology transfer experts.
Description
Material informatics, the integration of data science and materials science, has emerged as a transformative approach to discovering and optimizing materials. By leveraging big data, machine learning, artificial intelligence, and multiscale modeling, material informatics enables researchers to predict material properties, identify promising new materials, and streamline the development process. This symposium will focus on how these advanced tools and methodologies can be harnessed to enhance technology transfer and expedite the commercialization of innovative materials.
Targeted topics
List of topics and subtopics
- Data-Driven Material Discovery:
- Leveraging machine learning and AI to predict material properties and performance.
- Open-source academic tools
- Accelerating R&D with Material Informatics:
- Integrating informatics tools into traditional R&D workflows.
- Reducing time and cost from concept to prototype.
- Challenges in Technology Transfer:
- Overcoming barriers in the commercialization of new materials.
- Intellectual property management and licensing strategies.
- Industry Collaboration and Partnerships:
- Success stories of academia-industry collaborations.
- Building effective partnerships for technology transfer.
- Future Trends and Innovations:
- Emerging technologies in material informatics.
- The role of informatics in sustainable and green materials development.
OrganizerS
Dr. David Mercier
Ansys Inc. (FR)
Dr. Yoav Nahshon
Fraunhofer IWM (DE)