Innovative technology of cold UltraFast photo-magnetic recording and novel approach to UltraFast opto-spintronics (Q84286): Difference between revisions
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Revision as of 05:23, 29 October 2020
Project Q84286 in Poland
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Innovative technology of cold UltraFast photo-magnetic recording and novel approach to UltraFast opto-spintronics |
Project Q84286 in Poland |
Statements
3,300,000.0 zloty
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3,300,000.0 zloty
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100.0 percent
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1 May 2018
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30 April 2021
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UNIWERSYTET W BIAŁYMSTOKU
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Ultrafast all-optical control of magnetism using femtosecond and picosecond laser pulses is an intriguing and rapidly growing fundamental research area the outcome of which may have a high impact on the future technology. Project presents the new approach to concept of the novel technology of cold ultrafast photo-magnetic recording. The research programme is focusing on the advantages of this approach to magnetic memory which has the fastest switching speed and the exceptionally low energy consumption. We expect that the nonthermal photomagnetic switching based on an optical manipulation of spin-orbit interactions with low electrical field bias open up a plethora of opportunities for design and development of hybrid materials and new approach to ultrafast opto-spintronics. TEAM project will allow younger scientists be involved in advanced fundamental research and development of the data storage technology beyond state-of-the-art. (Polish)
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UltraFast all-optical control of magnetism using Femtosecond and picosecond laser pulses is an intriguing and rapidly growing fundamental research area the outcome of which may have a high impact on the future technology. Project presents the new approach to concept of the novel technology of cold UltraFast photo-magnetic recording. The research programme is focusing on the advantages of this approach to magnetic memory which has the fastest switching speed and the exceptionally low energy consumption. We expect that the nonthermal photomagnetic switching based on an optical manipulation of spin-orbit interactions with low electrical field bias open up a plethora of opportunities for design and development of hybrid materials and new approach to UltraFast opto-spintronics. Team project will allow younger scientists be involved in advanced fundamental research and development of the data storage technology beyond state-of-the-art. (English)
14 October 2020
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Identifiers
POIR.04.04.00-00-413C/17
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