Descrizione del progetto
Superconduttori avanzati per magneti ad alto campo
I magneti superconduttori sono elettromagneti estremamente potenti, capaci di generare campi magnetici maggiori a costi di esercizio inferiori. I magneti superconduttori vengono impiegati in una miriade di attrezzature scientifiche, tra cui, macchine RM, spettrometri RMN e acceleratori di particelle. Ciononostante, quelli disponibili sul mercato non risultano adatti alle grandi infrastrutture, quale il Laboratorio europeo dei campi magnetici (EMFL, European Magnetic Field Laboratory). Di recente, gli impianti dell’EMFL hanno proposto l’implementazione di magneti superconduttori ad alta temperatura. Il progetto SuperEMFL, finanziato dall’UE, intende sviluppare la tecnologia di superconduttività ad alta temperatura che offrirà una dimensione completamente nuova all’EMFL. Il progetto si prefigge di fornire campi magnetici superconduttori maggiori nonché geometrie innovative di magneti superconduttori alla comunità europea di utenti ad alto campo, che si tradurranno in una considerevole riduzione di energia del campo statico presso gli impianti dell’EMFL.
Obiettivo
The magnetic field is a powerful thermodynamic parameter to influence the state of any material system and such is an outstanding experimental tool for physics. To go beyond the conventional commercially available superconducting (SC) magnets, very large infrastructures such as the ones gathered within the European Magnetic Field Laboratory (EMLFL) are necessary. EMFL provides access to static resistive magnets (up to 38 T) and pulsed non-destructive (up to 100 T) and semi-destructive (up to 200 T) magnets for all qualified European researchers.
Some recent advances open the way for the implementation of high temperature superconductor (HTS) magnets at the EMFL facilities. The SuperEMFL design study aims to add through the development of the HTS technology an entirely new dimension to the EMFL that go beyond the commercial offer, providing the European high field user community with much higher SC fields and novel SC magnet geometries, like large-bore-high-flux magnets or radial access magnets.
The development of SC magnets that can partly replace current high-field resistive magnets will result in a significant reduction of the energy consumption of the static field EMFL facilities. This will strongly improve EMFL’s financial and ecological sustainability and at the same time boost its scientific performance and impact.
The high field values, the very low noise and vibration levels, and the possibility to run very long duration experiments will make high SC magnetic fields attractive to scientific communities that so far have rarely used the EMFL facilities (NMR, scanning probe, Fourier transform infrared spectroscopies, ultra-low temperature physics, electro-chemistry …).
All these new research possibilities will strengthen the scientific performance, efficiency and attractiveness of the EMFL and thereby of the European Research Area (ERA). The implementation of this strategy should therefore be considered as a major upgrade of the EMFL.
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Vedi altri progetti per questo bandoBando secondario
H2020-INFRADEV-2019-3
Meccanismo di finanziamento
RIA - Research and Innovation actionCoordinatore
75794 Paris
Francia