Antiferromagnetic beneficial effect and development of epitoxial bicillic antiferromagnes — two routes towards next-generation spintronics (Q84261): Difference between revisions
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(Removed claim: summary (P836): The main components of parent agents are responsible for the biological workers and ones.Antiferromagnes (AFMs), in whim magnetic order is accompaned and zero net magnetic timing, play roles in the spin off effect effect by establishing directive of FM as effective effect.Hwever, a demonstration of a demonstration of magneto-transport effects in AFMs and their ultra-fast magnetisation dynamic magnetisation provide that could replace FMS in spi...) |
(Created claim: summary (P836): The main active components of spintronic elements are ferromagnets (FMS), in which a net spin polarisation is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their Ul...) |
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The main active components of spintronic elements are ferromagnets (FMS), in which a net spin polarisation is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their UltraFast magnetisation dynamics make them potential candidates that could replace FMS in spintronic devices. In this project I propose two routes that will lead to development of antiferromagnetic spintronics. The first one is focused on tuning magnetic properties of AFMs via proximity effect in AFM/AFM bilayers. The second path concentrates on the epitaxial bimetallic AFMs. In both paths the feasibility of AFM spintronics with studied AFM materials will be presented. (English) | |||||||||||||||
| Property / summary: The main active components of spintronic elements are ferromagnets (FMS), in which a net spin polarisation is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their UltraFast magnetisation dynamics make them potential candidates that could replace FMS in spintronic devices. In this project I propose two routes that will lead to development of antiferromagnetic spintronics. The first one is focused on tuning magnetic properties of AFMs via proximity effect in AFM/AFM bilayers. The second path concentrates on the epitaxial bimetallic AFMs. In both paths the feasibility of AFM spintronics with studied AFM materials will be presented. (English) / rank | |||||||||||||||
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| Property / summary: The main active components of spintronic elements are ferromagnets (FMS), in which a net spin polarisation is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their UltraFast magnetisation dynamics make them potential candidates that could replace FMS in spintronic devices. In this project I propose two routes that will lead to development of antiferromagnetic spintronics. The first one is focused on tuning magnetic properties of AFMs via proximity effect in AFM/AFM bilayers. The second path concentrates on the epitaxial bimetallic AFMs. In both paths the feasibility of AFM spintronics with studied AFM materials will be presented. (English) / qualifier | |||||||||||||||
point in time: 14 October 2020
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Revision as of 12:32, 14 October 2020
Project in Poland financed by DG Regio
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Antiferromagnetic beneficial effect and development of epitoxial bicillic antiferromagnes — two routes towards next-generation spintronics |
Project in Poland financed by DG Regio |
Statements
787,310.0 zloty
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787,310.0 zloty
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100.0 percent
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1 March 2018
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29 February 2020
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AKADEMIA GÓRNICZO-HUTNICZA IM. STANISŁAWA STASZICA W KRAKOWIE
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The main active components of spintronic elements are ferromagnets (FMs), in which a net spin polarization is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their ultrafast magnetization dynamics make them potential candidates that could replace FMs in spintronic devices. In this project I propose two routes that will lead to development of antiferromagnetic spintronics. The first one is focused on tuning magnetic properties of AFMs via proximity effect in AFM/AFM bilayers. The second path concentrates on the epitaxial bimetallic AFMs. In both paths the feasibility of AFM spintronics with studied AFM materials will be presented. (Polish)
0 references
The main active components of spintronic elements are ferromagnets (FMS), in which a net spin polarisation is responsible for logical zeros and ones. Antiferromagnets (AFMs), in which magnetic order is accompanied by a zero net magnetic moment, play an important role in the spin-valve effect by establishing direction of FM reference layer via an exchange bias effect. However, recent demonstration of magneto-transport effects in AFMs and their UltraFast magnetisation dynamics make them potential candidates that could replace FMS in spintronic devices. In this project I propose two routes that will lead to development of antiferromagnetic spintronics. The first one is focused on tuning magnetic properties of AFMs via proximity effect in AFM/AFM bilayers. The second path concentrates on the epitaxial bimetallic AFMs. In both paths the feasibility of AFM spintronics with studied AFM materials will be presented. (English)
14 October 2020
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Identifiers
POIR.04.04.00-00-3E5D/17
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