Summary
The principal goal of the project is to combine research expertise in optics, crystallography and material science with efforts in material engineering to go beyond state-of-the-art in the development of highly efficient energy saving optical cells based on electro-, acousto- and nonlinear optical effects and designed to operate in optical and quasi-optical (sub-THz) ranges.
The idea of the project arises from recent advances in nano engineering combined with our technology for optimization of effects in anisotropic materials. We aim to benefit from enhanced anisotropic features, considering both materials with natural anisotropy and those with created and/or tailored anisotropy. Background will be developed by calculating parametric effects tensors for selected crystalline materials. Then, two routes to create samples characterized by the highest figures of merit will be implemented. 3D anisotropy analysis approach will be used for finding global extremes of effects under study and will provide technical information needed to manufacture novel nanocomposites with tailored anisotropy. Nanoengineering approach will be based on growing of nanocrystallites along preferable directions and incorporating them into porous host medium. It is expected to achieve considerable improvements of the operating energy characteristics for bulk and nanocomposite materials.
It is planned to reach the proof of concept stage for the optical cells with improved performance and compare their characteristics to those, available on the market. Measures will be undertaken for developing the concept into innovative products. The research will be linked to the large-scale training program for the Seconded Staff Members with specific individual objectives. Based on synergies between all participating organizations and networking activities we expect to increase Europe's attractiveness and competitiveness as leading destination for R&I, particularly in optic/nanoengineering research niche.
The idea of the project arises from recent advances in nano engineering combined with our technology for optimization of effects in anisotropic materials. We aim to benefit from enhanced anisotropic features, considering both materials with natural anisotropy and those with created and/or tailored anisotropy. Background will be developed by calculating parametric effects tensors for selected crystalline materials. Then, two routes to create samples characterized by the highest figures of merit will be implemented. 3D anisotropy analysis approach will be used for finding global extremes of effects under study and will provide technical information needed to manufacture novel nanocomposites with tailored anisotropy. Nanoengineering approach will be based on growing of nanocrystallites along preferable directions and incorporating them into porous host medium. It is expected to achieve considerable improvements of the operating energy characteristics for bulk and nanocomposite materials.
It is planned to reach the proof of concept stage for the optical cells with improved performance and compare their characteristics to those, available on the market. Measures will be undertaken for developing the concept into innovative products. The research will be linked to the large-scale training program for the Seconded Staff Members with specific individual objectives. Based on synergies between all participating organizations and networking activities we expect to increase Europe's attractiveness and competitiveness as leading destination for R&I, particularly in optic/nanoengineering research niche.
Unfold all
/
Fold all
More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/778156 |
Start date: | 01-02-2018 |
End date: | 31-07-2024 |
Total budget - Public funding: | 1 692 000,00 Euro - 1 692 000,00 Euro |
Cordis data
Original description
The principal goal of the project is to combine research expertise in optics, crystallography and material science with efforts in material engineering to go beyond state-of-the-art in the development of highly efficient energy saving optical cells based on electro-, acousto- and nonlinear optical effects and designed to operate in optical and quasi-optical (sub-THz) ranges.The idea of the project arises from recent advances in nano engineering combined with our technology for optimization of effects in anisotropic materials. We aim to benefit from enhanced anisotropic features, considering both materials with natural anisotropy and those with created and/or tailored anisotropy. Background will be developed by calculating parametric effects tensors for selected crystalline materials. Then, two routes to create samples characterized by the highest figures of merit will be implemented. 3D anisotropy analysis approach will be used for finding global extremes of effects under study and will provide technical information needed to manufacture novel nanocomposites with tailored anisotropy. Nanoengineering approach will be based on growing of nanocrystallites along preferable directions and incorporating them into porous host medium. It is expected to achieve considerable improvements of the operating energy characteristics for bulk and nanocomposite materials.
It is planned to reach the proof of concept stage for the optical cells with improved performance and compare their characteristics to those, available on the market. Measures will be undertaken for developing the concept into innovative products. The research will be linked to the large-scale training program for the Seconded Staff Members with specific individual objectives. Based on synergies between all participating organizations and networking activities we expect to increase Europe's attractiveness and competitiveness as leading destination for R&I, particularly in optic/nanoengineering research niche.
Status
SIGNEDCall topic
MSCA-RISE-2017Update Date
28-04-2024
Images
No images available.
Geographical location(s)