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Information × Registration Number 0225U003110, (0122U001908) , R & D reports Title Spin-dependent effects in nanostructured materials and structures of reduced dimension popup.stage_title Дослідження ефектів генерування та детектування електромагнітних сигналів у магнітних структурах зниженої розмірності. Аналіз та узагальнення отриманих результатів, розробка рекомендацій та оформлення звіту. Head Prokopenko Oleksandr V., Доктор фізико-математичних наук Registration Date 20-05-2025 Organization Taras Shevchenko National University of Kyiv popup.description1 Research of fundamental spin-dependent phenomena in nanostructured magnetic materials and structures of reduced dimension (films, wires, spintron nanostructures, magnon crystals) for the development of new directions of modern physics and electronics, improvement of existing and development of new magnetoelectronics devices. popup.description2 The relevance lies in the development of the physical foundations of the latest magnetic information and communication technologies related to the use of spin-dependent effects in structures of reduced dimensions. The aim of the work is to study fundamental spin-dependent phenomena in nanostructured magnetic materials and structures of reduced dimensions for the development of new areas of modern physics and electronics, the improvement of existing ones and the development of new magnetoelectronic devices. The main tasks: 1) To determine the conditions for the existence of microwave magnon-plasmon-polaritons on the surfaces of conductive magnetic films; to study their properties. 2) To study the spin-dependent effects of generation and detection of electromagnetic radiation in ferromagnetic (FM) and antiferromagnetic (AFM) spintronic nanostructures (SNS) with magnetic anisotropy of different nature. 3) Improve the theory of mutual synchronization of FM and AFM SNS in the case of different types of coupling, different spatial configurations of the SNS array. 4) Study the mechanisms of formation of magnetic nanomaterials. 5) Optimize existing ones and try to develop new magnetoelectronic devices based on the studied physical phenomena. Ideas and hypotheses: The project plans to theoretically (and, if possible, experimentally) investigate spin-dependent effects in FM and AFM SNS. It is assumed that the presence of magnetic anisotropy of various nature in SNS (including anisotropy in L10 materials) will allow choosing the optimal operating point for the implementation of magnetic dynamics in SNS. Product Description popup.authors Derevnina Zinayida М. Kondratovych Yurii M. Malyshev Oleksii V. Melkov Hennadii А. Popov Maksym O. Rodionova Tetiana V. Romanyuk Olena V. Sizhuk Andrii S. Slobodianiuk Denys V. Schtanko Oleh V. popup.nrat_date 2025-05-20 Close