The work performed during the entire project implementation period was a coordinated effort of enterprise and academia partners, structured into four main R&D domains: obtaining novel materials, developing reliable experimental techniques, characterization of relevant materials in an optical and sub-terahertz frequency range and modeling/designing prototypes of new devices based on these materials. In terms of tasks, the work was divided into nine work packages, each led by one of the participating organizations.
Several important research results were achieved concerning the project's main idea. The selection of the materials and their brief characterization have been completed. The chosen substances are categorized into two classes, including 12 crystalline materials and 6 different liquid crystals for bulk and nanocomposite applications.
A series of automated laboratory setups allowing the characterization of selected materials and the derivation of their important technological parameters were built and brought into operation. Existing experimental equipment for investigating the electromechanical, electro-, piezo-, and acoustic properties of crystals has been upgraded.
Various methods for obtaining ordered anisotropic membrane-type nanostructures were investigated. Preliminary results show that the proposed technique is viable, and the right choice of growing conditions for nanocomposite crystalline materials is crucial for obtaining effective, crystalline electro-optical and nonlinear optical materials.
Aiming to create controllable elements for next-generation high-frequency electronics, the team investigated the tunability of bulk crystalline materials in the sub-terahertz range using an electric field, acoustic wave, optical radiation, and other external interactions. The team identified the most important phenomena that can be potentially utilized to obtain the desired effect.
The approach for finding the best achievable values of the linear electro-optic and nonlinear optical effect in crystals was developed, documented, and applied to several sample materials. Related findings of fundamental interest were published in high-impact journals.
The efficiency of the second harmonic generation process in selected crystalline materials was analyzed, and based on this analysis, universal software tools were created.
To facilitate the project results dissemination, the team contributed to the organization of 14 international conferences such as:
TCSET-2018 (Ukraine), NAP-2018 (Ukraine), ICTON-2019 (France), IMNE-2019 (Poland), TCSET-2020 (Ukraine), RNAOPM-2020 (Ukraine), NAP-2021 (Ukraine), OMEE-2021 (Ukraine), TCSET-2022 (Ukraine), NAP-2022 (Poland), IMNE-2022 (Ukraine), ICTON-2023 (France), IMNE-2023 (Ukraine), IMNE-2024 (Ukraine).