Summary
The ability to switch magnets between two stable bit states with the help of a magnetic field is the main principle of modern data storage technology. Due to many new ideas, originating from fundamental research during the last 50 years, this technology has been developing in a breath-taking fashion. However, the heat produced by modern data centers is already a serious limitation to further increase their performance. It is not clear how to improve this situation which in future might contribute greatly to the global warming and energy crisis.
Our proposal is inspired by several recent breakthroughs allowing ultrafast and energy efficient magnetic recording with the help of light. COMRAD will explore novel routes for the fastest possible and least dissipative magnetic switching in random access devices by bringing together the two disciplines of ultrafast magnetism and spin-orbitronics, creating sub-100 ps stimuli in spin-orbitronics and pushing the latter into a regime beyond the limitations of equilibrium thermodynamics.
The ambition of COMRAD is to train ESRs in such a way that they gain a broad understanding of the challenges in the entire process of emergence and development of opto-magnetic data storage, from fundamental research to device and failure analysis. This is a new and disruptive technology with the potential to revolutionize information storage and manipulation. Working on the ambitious goals in the Consortium of academic and multiscale industrial partners, the trained ESRs will develop unique cross-disciplinary skills in applying advanced experimental and computational techniques, state-of-the-art device engineering and analysis. Being a new generation of scientists with an affinity to commercial enterprises and ambassadors of science in commerce, COMRAD-ESRs will be able to strengthen European innovation capacity feeling the frighteningly increasing gap between fundamental science and commercial applications.
Our proposal is inspired by several recent breakthroughs allowing ultrafast and energy efficient magnetic recording with the help of light. COMRAD will explore novel routes for the fastest possible and least dissipative magnetic switching in random access devices by bringing together the two disciplines of ultrafast magnetism and spin-orbitronics, creating sub-100 ps stimuli in spin-orbitronics and pushing the latter into a regime beyond the limitations of equilibrium thermodynamics.
The ambition of COMRAD is to train ESRs in such a way that they gain a broad understanding of the challenges in the entire process of emergence and development of opto-magnetic data storage, from fundamental research to device and failure analysis. This is a new and disruptive technology with the potential to revolutionize information storage and manipulation. Working on the ambitious goals in the Consortium of academic and multiscale industrial partners, the trained ESRs will develop unique cross-disciplinary skills in applying advanced experimental and computational techniques, state-of-the-art device engineering and analysis. Being a new generation of scientists with an affinity to commercial enterprises and ambassadors of science in commerce, COMRAD-ESRs will be able to strengthen European innovation capacity feeling the frighteningly increasing gap between fundamental science and commercial applications.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/861300 |
| Start date: | 01-06-2020 |
| End date: | 30-11-2024 |
| Total budget - Public funding: | 3 776 243,40 Euro - 3 776 243,00 Euro |
Cordis data
Original description
The ability to switch magnets between two stable bit states with the help of a magnetic field is the main principle of modern data storage technology. Due to many new ideas, originating from fundamental research during the last 50 years, this technology has been developing in a breath-taking fashion. However, the heat produced by modern data centers is already a serious limitation to further increase their performance. It is not clear how to improve this situation which in future might contribute greatly to the global warming and energy crisis.Our proposal is inspired by several recent breakthroughs allowing ultrafast and energy efficient magnetic recording with the help of light. COMRAD will explore novel routes for the fastest possible and least dissipative magnetic switching in random access devices by bringing together the two disciplines of ultrafast magnetism and spin-orbitronics, creating sub-100 ps stimuli in spin-orbitronics and pushing the latter into a regime beyond the limitations of equilibrium thermodynamics.
The ambition of COMRAD is to train ESRs in such a way that they gain a broad understanding of the challenges in the entire process of emergence and development of opto-magnetic data storage, from fundamental research to device and failure analysis. This is a new and disruptive technology with the potential to revolutionize information storage and manipulation. Working on the ambitious goals in the Consortium of academic and multiscale industrial partners, the trained ESRs will develop unique cross-disciplinary skills in applying advanced experimental and computational techniques, state-of-the-art device engineering and analysis. Being a new generation of scientists with an affinity to commercial enterprises and ambassadors of science in commerce, COMRAD-ESRs will be able to strengthen European innovation capacity feeling the frighteningly increasing gap between fundamental science and commercial applications.
Status
SIGNEDCall topic
MSCA-ITN-2019Update Date
28-04-2024
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Organisations
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| STICHTING KATHOLIEKE UNIVERSITEIT (SKU/RU) (Coördinator)
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| AGENCIA ESTATAL CONSEJO SUPERIOR DE INVESTIGACIONES CIENTIFICAS
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| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
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| Eindhoven University of Technology
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| FORSCHUNGSZENTRUM JULICH GMBH (JUELICH)
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| IFEVS
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| THALES SA
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| THE UNIVERSITY OF CAMBRIDGE
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| UNIVERSITAET REGENSBURG
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| UNIVERSITE DE LORRAINE (UL)
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| UNIVERSITY OF LANCASTER
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| UNIVERSITY OF YORK
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| UNIWERSYTET W BIALYMSTOKU