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001     882689
005     20230825115930.0
024 7 _ |a G:(EU-Grant)860060
|d 860060
|2 CORDIS
024 7 _ |a G:(EU-Call)H2020-MSCA-ITN-2019
|d H2020-MSCA-ITN-2019
|2 CORDIS
024 7 _ |a corda__h2020::860060
|2 originalID
035 _ _ |a G:(EU-Grant)860060
150 _ _ |a Magnetism and the effects of Electric Field
|y 2019-10-01 - 2024-03-31
371 _ _ |a University of Salamanca - Centro de Investigación del Cáncer
|b CIC
|d Spain
|e http://www.cicancer.org/en
|v CORDIS
371 _ _ |a Singulus Technologies AG
|b Singulus
|d Germany
|e http://www.singulus.de
|v CORDIS
371 _ _ |a Instituto Nazionale di Ricerca Metrologica
|b INRiM
|d Italy
|e http://www.inrim.it/
|v CORDIS
371 _ _ |a University of Leeds
|b University of Leeds
|d United Kingdom
|e http://www.leeds.ac.uk/
|v CORDIS
371 _ _ |a SPIN-ION TECHNOLOGIES
|d France
|e http://www.spin-ion.com
|v CORDIS
371 _ _ |a UNIVERSITE PARIS-SACLAY
|d France
|e https://www.universite-paris-saclay.fr/fr
|v CORDIS
371 _ _ |a AALTO KORKEAKOULUSAATIO SR
|b AALTO
|d Finland
|e http://www.aalto.fi
|v CORDIS
371 _ _ |a SENSITEC GMBH
|d Germany
|e http://www.sensitec.com
|v CORDIS
371 _ _ |a Eindhoven University of Technology
|b TU/e
|d Netherlands
|e http://www.tue.nl/
|v CORDIS
371 _ _ |a CNRS - Institut des Sciences Biologiques
|b INSB
|d France
|e http://www.cnrs.fr/insb/
|v CORDIS
371 _ _ |a Paris Dauphine University
|b Paris Dauphine University
|d France
|e http://www.dauphine.fr/en/welcome.html
|v CORDIS
371 _ _ |a Johannes Gutenberg University of Mainz
|b Johannes Gutenberg University of Mainz
|d Germany
|e http://www.uni-mainz.de/eng/
|v CORDIS
372 _ _ |a H2020-MSCA-ITN-2019
|s 2019-10-01
|t 2024-03-31
450 _ _ |a MagnEFi
|w d
|y 2019-10-01 - 2024-03-31
510 1 _ |0 I:(DE-588b)5098525-5
|a European Union
|2 CORDIS
680 _ _ |a MagnEFi is a training network of European experts assembled to provide enhanced training and education to early stage researchers on the topic of electric field effects on nanoscale magnetic structures. The goal is to train the next generation to work in this fast rising and key field of GreenIT. Electric fields may be applied to nanoscale magnetic structures in a variety of ways: either directly as a voltage gate, coupled via a ferroelectric or piezoelectric material that strains the nanomagnet, or using light. Addressing the effect of electric fields on the properties of nanoscale magnetic structures has become increasingly important in the search for efficient methods of manipulating nanomagnetism. Research in this area is expected ultimately to lead to ultralow power devices for computation and communication with new functionalities. The consortium that has come together to deliver this training is uniquely qualified to do so, consisting of world-leading experts in condensed matter physics and leading private companies, along with a range of associated partners spanning basic research, machine tool development, industrial and consumer products. The consortium provides a rich training environment that is both international and intersectoral, where the fellows will both study at the cutting edge of science and technology, and also come to appreciate the breadth of the field in terms of its intellectual challenges, commercial concerns and relationship to society’s need for ever more powerful information technologies with a reduced environmental footprint. This will enable them, in their future careers, to contribute to the strengthening of both the European Research Area and the European Information and Communication industry, particularly GreenIT, an especially important and growing sector for EU economic development.
909 C O |o oai:juser.fz-juelich.de:882689
|p authority:GRANT
|p authority
970 _ _ |a oai:dnet:corda__h2020::67ff5b86eedc4d15513d7962078c6b87
980 _ _ |a G
980 _ _ |a CORDIS
980 _ _ |a AUTHORITY

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