Basis of Mathematics in nanomedicine structures and life sensing
| Reference No. | 2023b004 |
|---|---|
| Type/Category | Grant for International Project Research-Workshop (I) |
| Title of Research Project | Basis of Mathematics in nanomedicine structures and life sensing |
| Principal Investigator | Stanislaw Janeczko(Faculty of Mathematis and Information Science, Warsaw University of Technology / Professor) |
| Research Period |
September 25, 2023. - September 29, 2023. |
| Keyword(s) of Research Fields | Mathematical physics, Mathematics of Data Science and Machine Learning, Mathematical Medicine and Biology, Control and Dynamical Systems (including differential equations),Scientific Computing, Mathematical modelling, Nanotechnology in medicine |
| Abstract for Research Report | The objective of the workshop is to discuss various Mathematical bases that are indispensable in studying nanomedicine structures and in developing life sensing technologies, both of which are important research themes for the Polish team. For that purpose, mainly the Japanese team will propose various Mathematical theories and methods that can be effectively used for innovative development of the themes. The Polish team is studying nanoparticles with well-defined chemical compositions, which can act as building blocks for the construction of functional structures, such as highly ordered aggregates, as well as porous and hollow aggregates. A geometric model that considers the tight packing of spheres into frustrated clusters in quasi-crystal forms with short-range icosahedral symmetry will be discussed and compared to experimentally produced structures important for innovative pharmacological drug delivery substances. For that purpose, approaches from discrete differential geometry or topology are expected to play important roles. We are creating instruments of analyzing the chemical composition of volatile substances, enabling further computer analysis and classification of the associated smells. To some extent, such a device can be considered an electronic equivalent of animals' sense organs. The basic aim is to recognize and model the fundamental nature of the senses. It is already experienced that it depends more on the applied artificial intelligence solutions than on the quality and precision of semiconductors or optical sensors. In our project, practical methods for structure prediction of two-dimensional materials for sensor applications, based on neural network-driven evolutionary techniques, will be investigated. For that purpose, topological techniques or evolutional computation will be very important. In 2011 the World Health Organization specified that mobile phones could lead to specific forms of brain tumors. Adopting 5G means more signals carrying more energy through the high-frequency spectrum, with more transmitters located closer to people’s homes and workplaces. This problem opens a whole Pandora’s box of trouble for us – and our planet – namely, potential risks to both human and environmental health. In our program, we plan to use physics and mathematics to design and fabricate advanced nanostructured materials for protecting living organisms from an excess of high-frequency electromagnetic radiation. As a result, we plan to implement custom-designed, sophisticated, specially shielded, and shape-optimized THz and MMW optics for such devices, with emphasis put on the graphene-based attenuation, Faraday-cage-like metallic structures, and structural anti-reflection coatings. For this purpose, algebraic study of material structures, multi-objective optimization, and singularity theory will be very important. |
| Organizing Committee Members (Workshop) Participants (Short-term Joint Usage) |
Stanislaw Janeczko(Center for Advanced Studies, Warsaw University of Technology / Professor) Osamu Saeki(Institute of Mathematics for Industry, Kyushu University / Professor) Wojciech Domitrz(Faculty of Mathematics and Information Science, Warsaw University of Technology / Professor ) |