CORDIS fournit des liens vers les livrables publics et les publications des projets HORIZON.
Les liens vers les livrables et les publications des projets du 7e PC, ainsi que les liens vers certains types de résultats spécifiques tels que les jeux de données et les logiciels, sont récupérés dynamiquement sur OpenAIRE .
Livrables
Defining the Quality Management Plan - introducing formal processes for the project life-cycle, and the evaluation and control of the deliverables and the project itself according to the quality standards and plans.
Proof-of-concept samples for PE EPR spectroscopy (s’ouvre dans une nouvelle fenêtre)UHV evaporation of an analysed material on the samples with and without PS (reference samples). Utilizing a patterned photoresist to provide selective deposition to specific sites (increase of the relative antenna signal contribution). Application of samples for PE THz EPR spectroscopy.
Scientific communication (s’ouvre dans une nouvelle fenêtre)Summary of the scientific communication containing at least 10 papers in impacted journals, at least 8 conference presentations during the duration of the project.
Interim CDE plan (s’ouvre dans une nouvelle fenêtre)Interim plan for the communiation, dissemination, and exploitation of project related activities and outputs. The CDE plan will be continuously updated according to project needs.
Proof-of-concept samples for PE EPR microscopy (s’ouvre dans une nouvelle fenêtre)UHV evaporation of an analysed material on the samples with and without PS (reference samples). Utilizing a patterned photoresist to provide selective deposition to specific sites (increase of the relative antenna signal contribution). Application of samples for PE THz EPR microscopy.
Updated Quality Management Plan (s’ouvre dans une nouvelle fenêtre)Updating the Quality Management Plan - introducing formal processes for the project life-cycle, and the evaluation and control of the deliverables and the project itself according to the quality standards and plans.
Specifications of PE EPR microscope (s’ouvre dans une nouvelle fenêtre)Discussion of detailed design criteria and prioritizing the constrictions of individual functional units of PE EPR microscope to be coherent with other units and posses required functionality.
Plasmon-enhanced EPR experiments (s’ouvre dans une nouvelle fenêtre)Application of the optimized THz apparatus and samples prepared for PE THz EPR experiments – assessment of the magnetic sensing field enhancement caused by PS, the scope and limitations of the setup. Continuous-improvement feed-back loop.
Data management plan (s’ouvre dans une nouvelle fenêtre)Data management plan specifying the data management life cycle for the data generated and processed within the project. Data management plan will continuously updated based on the needs.
Final CDE plan (s’ouvre dans une nouvelle fenêtre)Final version of the plan for the communiation, dissemination, and exploitation activities.
PS design for plasmon enhanced EPR (s’ouvre dans une nouvelle fenêtre)Theoretical simulations of local plasmon resonances in various PS, identification of the most suitable antennas for the EPR enhancement. Considered geometries based on the funnelling of current (e.g. diabolo antennas) and/or circulation of current (e.g. split-ring resonators).
Applications of PE EPR (s’ouvre dans une nouvelle fenêtre)Report on applications of newly developed PE THZ EPR method: Room temperature: ferromagnetic nano/microstructures fabricated by EBL and FIB, a commercial hard disk. Low temperature: Molecular nanomagnets (transition metal phthalocyanine thin films on various substrates).
Concept of PS (s’ouvre dans une nouvelle fenêtre)Critical discussion of various concepts of PS, definition of spatial restriction for implementation to cantilevers and identification of relevant fabrication methodology.
Fabrication of a folded PS by EBL/FIB on longer/wider tips (e.g. needles, sapphire shards,…) glued to cantilevers or watch tuning forks.
PS for PE EPR experiments in THz (s’ouvre dans une nouvelle fenêtre)Characterization of plasmon resonances by THz spectroscopy (USTUTT, NGU). Optimization of coupling of THz radiation to PS - design of a quasi-optics and its installation into the EPR apparatus. Utilizing the results as a feed-back for optimization of PS with respect to PE THz EPR.
Optimized cantilever tips for PE EPR microscopy (s’ouvre dans une nouvelle fenêtre)Fabrication of a folded PS by EBL/FIB on longer/wider tips (e.g. needles, sapphire shards,…) glued to cantilevers or watch tuning forks: Optimized structures.
PS with enhanced magnetic field (s’ouvre dans une nouvelle fenêtre)Fabrication of metallic and doped semiconductor PS by lithography (electron, photo). Graphene PS – patterning of exfoliated and CVD graphene by lithography, plasma etching, Special efforts - doping (electric or chemical) of graphene.
SPM unit for PE EPR microscopy: Prototype (s’ouvre dans une nouvelle fenêtre)Assembly of a scanning sample stage of SPM from a X, Y, Z scanning piezo unit (X, Y: 100 × 100 μm2) and closed loop x-y-z piezo sample manipulator for a precise navigation to a specific sample site. Equipping the head carrying the cantilever with a cantilever-deflection detection system and a piezo providing cantilever oscillations (non-contact mode). Working prototype.
SPM unit for PE EPR microscopy: Progress report (s’ouvre dans une nouvelle fenêtre)Assembly of a scanning sample stage of SPM from a X, Y, Z scanning piezo unit (X, Y: 100 × 100 μm2) and closed loop x-y-z piezo sample manipulator for a precise navigation to a specific sample site. Equipping the head carrying the cantilever with a cantilever-deflection detection system and a piezo providing cantilever oscillations (non-contact mode). Progress report.
Platform for PE EPR microscopy (s’ouvre dans une nouvelle fenêtre)Installation of the SPM unit delivered in D2.1-D2.3 into a LHe cryostat of the EPR apparatus – assembly of a platform-prototype for PE THz EPR microscopy. Testing and optimization of the platform.
Implementation of Open research data pilot in the project.
Visual identity of the project including the logo. Website and visibility at social networks.
Publications
Auteurs:
Chao Chen, Shu Chen, Ricardo P.S.M. Lobo, Carlos Maciel-Escudero, Martin Lewin, Thomas Taubner, Wei Xiong, Ming Xu, Xinliang Zhang, Xiangshui Miao, Peining Li, Rainer Hillenbrand
Publié dans:
ACS Photonics, Numéro 7/12, 2020, Page(s) 3499-3506, ISSN 2330-4022
Éditeur:
American Chemical Society
DOI:
10.1021/acsphotonics.0c01541
Auteurs:
Michal Kern, Lorenzo Tesi, David Neusser, Nadine Rußegger, Mario Winkler, Alexander Allgaier, Yannic M. Gross, Stefan Bechler, Hannes S. Funk, Li‐Te Chang, Jörg Schulze, Sabine Ludwigs, Joris van Slageren
Publié dans:
Advanced Functional Materials, Numéro 16. 11. 2020, 2020, Page(s) 2006882, ISSN 1616-301X
Éditeur:
John Wiley & Sons Ltd.
DOI:
10.1002/adfm.202006882
Auteurs:
Lorenzo Tesi, Dominik Bloos, Martin Hrtoň, Adam Beneš, Mario Hentschel, Michal Kern, Alisa Leavesley, Rainer Hillenbrand, Vlastimil Křápek, Tomáš Šikola, Joris Slageren
Publié dans:
Small Methods, Numéro 2021, 2021, Page(s) 2100376, ISSN 2366-9608
Éditeur:
Wiley-VCH GmbH
DOI:
10.1002/smtd.202100376
Auteurs:
Stefan Mastel, Alexander A. Govyadinov, Curdin Maissen, Andrey Chuvilin, Andreas Berger, Rainer Hillenbrand
Publié dans:
ACS Photonics, Numéro 5/8, 2018, Page(s) 3372-3378, ISSN 2330-4022
Éditeur:
American Chemical Society
DOI:
10.1021/acsphotonics.8b00636
Auteurs:
Curdin Maissen, Shu Chen, Elizaveta Nikulina, Alexander Govyadinov, Rainer Hillenbrand
Publié dans:
ACS Photonics, Numéro 6/5, 2019, Page(s) 1279-1288, ISSN 2330-4022
Éditeur:
American Chemical Society
DOI:
10.1021/acsphotonics.9b00324
Auteurs:
Martin Hrtoň, Andrea Konečná, Michal Horák, Tomáš Šikola, Vlastimil Křápek
Publié dans:
Physical Review Applied, Numéro 13/5, 2020, ISSN 2331-7019
Éditeur:
American Physical Society
DOI:
10.1103/physrevapplied.13.054045
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