Paramagnon-Enhanced Spin Currents in a Lattice near the Curie Point

Finazzi, Marco; Bottegoni, Federico; Zucchetti, Carlo; Isella, Giovanni; Ciccacci, Franco

doi:10.1038/s41598-018-35336-0

Sci Rep

2018

DOI: 10.1038/s41598-018-35336-0

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Paramagnon-Enhanced Spin Currents in a Lattice near the Curie Point

Marco Finazzi

Federico Bottegoni

Carlo Zucchetti

et al.

Abstract: Spin transport phenomena have been shown to be highly enhanced when the temperature approaches the Curie point of the material sustaining a spin flow. Here we propose a simple - yet unifying - explanation for such enhancements, based on a random-phase model accounting for the spin fluctuations within a ferromagnetic material in the paramagnetic phase. We show that pure spin currents carried by conduction electrons injected into a paramagnetic lattice of mutually interacting localized magnetic moments can be en… Show more

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2023

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References 41 publications

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Bridging Performance Gaps: Exploring New Classes of Materials for Future Spintronics Technological Challenges

Al‐Qatatsheh,

Juodkazis,

Hameed

2023

Adv Quantum Tech

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Technological challenges, such as insufficient computation power, inefficient data storage, and unsafe communication, may not be tackled by currently utilized semiconductors or superconductors, which are still far from meeting the requirements of quantum‐age applications. Spintronics, focused on electron transport phenomena dependent on spin, holds promise as an advanced technology. Nevertheless, most recent quantum technologies adopted by leading businesses and start‐ups rely heavily on others, and there is a race to increase the number of qubits to gain a computational advantage. Therefore, it is crucial to consider new classes of materials instead of the conventional ones. Developing high‐performance organic spintronics based on new classes of materials, namely, ionic liquids (ILs), liquid and soft crystals, and macroradicals, can support high‐speed and low‐power computing applications, offering higher spin‐relaxation times in the order of microsecond at room temperature. This perspective discusses the key challenges of the currently utilized inorganic semiconductors, small molecules, and π‐conjugated polymers. It also discusses how the new classes of organic spintronics can bridge these performance gaps.

show abstract

Bridging Performance Gaps: Exploring New Classes of Materials for Future Spintronics Technological Challenges

Al‐Qatatsheh,

Juodkazis,

Hameed

2023

Adv Quantum Tech

View full text Add to dashboard Cite

show abstract

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Paramagnon-Enhanced Spin Currents in a Lattice near the Curie Point

Cited by 1 publication

References 41 publications

Bridging Performance Gaps: Exploring New Classes of Materials for Future Spintronics Technological Challenges

Bridging Performance Gaps: Exploring New Classes of Materials for Future Spintronics Technological Challenges

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