The list of international projects SAS
Institute of Inorganic Chemistry
Novel high-entropy materials for sustainable energy
Nové vysoko-entropické materiály pre udržateľnú energetiku
| Duration: |
3.10.2023 - 2.10.2027 |
| Program: |
COST |
| Project leader: |
Ing. Tatarko Peter PhD. |
| Annotation: | Materials have played a decisive role in nearly all rupture technologies in the industrial history of our society. Faced with the current climate, geopolitical and humanitarian crisis, many international and regional entities (political, industrial and scientific alike) recognize the importance of a strong materials innovation ecosystem for driving the clean energy transition. In response, self-driving laboratories (SDL) (a.k.a. MAPs – materials acceleration platforms) are created at institutional, regional and international levels. SDLs integrate combinatorial synthesis, high-throughput characterization, automated analysis and machine learning for fast-track discovery and optimization of advanced materials. While these platforms are proving their effectiveness in producing advanced materials with targeted functionalities and physical properties, a large margin of improvement still exists. Streamlining materials integration into components and to safe and sustainable products is one example challenge in order to enable rupture technology. Another challenge is that of geographical concentration of MAPs that practically excludes a substantial fraction of research labs and tech-companies in Europe from contributing and benefiting from such platforms. Finally, next generation material science researchers need to develop new skills to be able to integrate such systemic and automated approach into their future R&D framework. To this end, EU-MACE will become an ecosystem for accelerated materials development at the user end, gathering researchers and stakeholders with state-of-the-art digital and material competences combined with the market/social pull. Our inclusive & systemic approach will lay the foundation for a future centre of excellence for advanced functional materials to assist transition toward a united and stronger EU. |
Novel high entropy diborodicarbides for ultra-high temperature applications
Nové vysokoentropické borido-karbidy pre vysokoteplotné aplikácie
Novel Ultra-High Temperature Ceramic Matrix Cpmposites for Application in Harsh Aerospace Environments
Novel Ultra-High Temperature Ceramic Matrix Cpmposites for Application in Harsh Aerospace Environments
Relativistic Effects on Magnetic Resp
Relativistické vplyvy na magnetickú odozvu
| Duration: |
1.7.2025 - 30.6.2027 |
| Program: |
Multilateral - other |
| Project leader: |
Mgr. Komorovský Stanislav PhD. |
| Annotation: | The REMAG project aims to unveil the role of relativistic effects on the molecular structure, bond energies, magnetically induced current density, and NMR parameters of heavy-element compounds, focusing on transition-metal complexes. The proposed research will be carried out in collaboration between four partners at institutions in Bratislava (IIC SAS, Slovakia), Brno (CEITEC MU, Czech Republic), Dijon (ICMUB, France), and Salzburg (PLUS, Austria). We plan a) to develop and implement in the ReSpect program the decomposition of the current density at the relativistic level of theory; b) to develop generalizing concepts across the periodic table of the elements of the impact of relativistic effects on properties of heavy transition metal hybrids and interpret them in the light of molecular orbital theory; c) to elucidate the role of relativistic effects on magnetically induced current density and NMR parameters of heavy transition metal complexes; and d) to analyze relativistic effects on bonds between transitional metals and non-hydrogen atoms. |
Development of new brazing fillers for joining of high entropy borides
Vývoj nových spojovacích materiálov pre vysokoentropické boridy
| Duration: |
1.1.2025 - 31.12.2026 |
| Program: |
Mobility |
| Project leader: |
Ing. Tatarko Peter PhD. |
| Annotation: | Main objective of this proposals is to establish a common framework regarding the joining of High Entropy Borides (HEBs); this includes the production of HEBs by SPS and their characterisation in terms of wetting and interfacial reactivity with the aid of thermodynamic considerations. This type of research is multidisciplinary and the materials involved are novel, so it is believed that the outcomes will go significantly beyond the current state of the art. It is expected that the HEBs in combination with the tested alloys will exhibit promising results in view of joining processes. |
The total number of projects: 5
