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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Yang, H.
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (30/30 displayed)
- 2024Evidence of non-isentropic release from high residual temperatures in shocked metals measured with ultrafast x-ray diffractioncitations
- 2023How the EU project "Online Microstructure Analytics" advances inline sensing of microstructure during steel manufacturing
- 2023How the EU project "Online Microstructure Analytics" advances inline sensing of microstructure during steel manufacturing
- 2021Creep Characteristics of Metal Matrix Compositescitations
- 2021Properties of Mg-based Metal Matrix Nanocomposites Processed by High Shear Dispersion Technique (HSDT) - A Reviewcitations
- 2020Effects of heat treatment on the microstructural evolution and creep resistance of Elektron21 alloy and its nanocompositecitations
- 2020Microstructure-corrosion behaviour relationship of micro-alloyed Mg-0.5Zn alloy with the addition of Ca, Sr, Ag, In and Cucitations
- 2020Profiling of gastric cancer cell-surface markers to achieve tumour-normal discrimination. citations
- 2020Crystal structure and metallization mechanism of the pi-radical metal TED (vol 11, pg 11699, 2020)
- 2020Proton-transfer-induced 3D/2D hybrid perovskites suppress ion migration and reduce luminance overshootcitations
- 2020Individual/synergistic effects of Al and AlN on the microstructural evolution and creep resistance of Elektron21 alloycitations
- 2019Influences of AlN/Al Nanoparticles on the Creep Properties of Elektron21 Prepared by High Shear Dispersion Technologycitations
- 2019Em sensor array system and performance evaluation for in-line measurement of phase transformation in steelcitations
- 2019Time-sequential corrosion behaviour observation of micro-alloyed Mg-0.5Zn-0.2Ca alloy via a quasi-in situ approachcitations
- 2019Application of Hydrides in Hydrogen Storage and Compression: Achievements, Outlook and Perspectivescitations
- 2019Application of hydrides in hydrogen storage and compression: Achievements, outlook and perspectivescitations
- 2019Influences of Al and high shearing dispersion technique on the microstructure and creep resistance of Mg-2.85Nd-0.92Gd-0.41Zr-0.29Zn alloycitations
- 2018Copper Electroplating with Polyethylene Glycol: Part II. Experimental Analysis and Determination of Model Parameterscitations
- 2018Product uniformity control - A research collaboration of european steel industries to non-destructive evaluation of microstructure and mechanical properties:
- 2017Large enhancement of the spin Hall effect in Au by scattering with side-jump on Ta impuritiescitations
- 2017Large enhancement of the spin Hall effect in Au by scattering with side-jump on Ta impuritiescitations
- 2016Carbon Nanotubes Integration on Silicon
- 2016Efficient Visible Quasi-2D Perovskite Light-Emitting Diodescitations
- 2016Perovskite Light-Emitting Diodes: Efficient Visible Quasi-2D Perovskite Light-Emitting Diodes (Adv. Mater. 34/2016)citations
- 2016Hybrid integration of Carbon nanotubes into silicon slot photonic structurescitations
- 2015Protecting nickel with graphene spin-filtering membranes:A single layer is enoughcitations
- 2015Protecting nickel with graphene spin-filtering membranescitations
- 2015Integration of carbon nanotubes in silicon resonators
- 2011Origin of magnetic switching field distribution in bit patterned media based on pre-patterned substratescitations
- 2003[A case-control study on natural-resistance-associated macrophage protein 1 gene polymorphisms and susceptibility to pulmonary tuberculosis].
Places of action
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article
Large enhancement of the spin Hall effect in Au by scattering with side-jump on Ta impurities
Abstract
We present measurements of the Spin Hall Eect (SHE) in AuW and AuTa alloys for a large range of W or Ta concentrations by combining experiments on lateral spin valves and Ferromagnetic-Resonance/spin pumping technique. The main result is the identication of a large enhancement of the Spin Hall Angle (SHA) by the side-jump mechanism on Ta impurities, with a SHA as high as + 0.5 (i.e 50%) for about 10% of Ta. In contrast the SHA in AuW does not exceed + 0.15 and can be explained by intrinsic SHE of the alloy without signicant extrinsic contribution from skew or side-jump scattering by W impurities. The AuTa alloys, as they combine a very large SHA with a moderate resistivity (smaller than 85 µΩ.cm), are promising for spintronic devices exploiting the SHE. A goal of spintronics is to generate, manipulate and detect spin currents for the transfer and manipulation of information, thus allowing faster and low-energy consuming operations. Since the discovery of the Giant Magnetoresistance a "classical" way to produce spin currents was to take advantage of ferromagnetic materials and their two different spin channel conductivities [1, 2]. In the last decade the rediscovery and study of spin orbit interaction eects brought new insights into creation mechanisms of spin currents. Among all mechanisms the spin Hall eect (SHE) focused a lot of attention as it allows the generation of spin currents from charge current and vice versa [3]. Despite being observed only a decade ago [46] these eects are already ubiquitous within the Spintronics as standard spin-current generators and detectors [7 9]. The conversion coecient between charge and spin currents is called the spin Hall angle (SHA) and is dened as Θ SHE = ρ xy /ρ xx , ratio of the non-diagonal and diagonal terms of the resistivity tensor. One of the main interests of the SHE is to provide a new paradigm for Spintronics where non-magnetic materials becomes active spin current source and detector. Until now most of the reports focused on single heavy metals and intrinsic SHE mechanisms, the main materials of interest being: Pt, Ta, W, and some oxydes. With intrinsic mechanisms the SHA is typically proportional to the resistivity of the heavy metal, and generally, a large value of the SHA is associated with a high resistivity (i.e.-0.3 for the SHA in β − W is associated with 263 µΩ.cm [10]) which limits the current density and the resulting spin transfer torques on the mag-netisation of an adjacent metallic ferromagnetic material. Extrinsic SHE mechanisms associated with the spin dependent scattering on impurities or defects are an alternative to generate transverse spin currents [11]. Two particular scattering mechanisms have been identied: the skew scattering [12] providing a non-diagonal term of the resistivity tensor proportional to the longitudinal resistivity (ρ xy ∝ ρ xx) and the side jump [13] for which the non-diagonal term is proportional to the square of the resistivity (ρ xy ∝ ρ 2 xx). For instance, the skew scattering mechanism have been observed in CuIr, CuBi, CuPb alloys (SHA=0.02,-0.24,-0.13, resp.) [14, 15]. The intrinsic mechanism from Berry curvature in the conduction band gives the same dependence ρ xy ∝ ρ 2 xx as the side-jump contribution so that, for example the SHE of AuPt (SHA=0.3 at max.) alloys could be explained by a predominant intrinsic eect rather than ascribed to side-jump[16]. In this letter we present a study of Au-based alloys with W and T a impurities. We demonstrate that the side-jump scattering mechanism dominates in AuTa alloys, and generates high spin Hall angles (up to + 0.5) with the additional advantage of resistivities (ρ AuT a < 85µΩ.cm) smaller than in most materials with SHA in the same range. By contrast in AuW alloys the SHE is mainly due to only the intrinsic mechanism and is denitely smaller than in AuTa. This dierence between AuTa and AuW is supported by ab − initio calculations. The alloys were fabricated by DC magnetron sputtering by co-deposition of the two pure materials. The concentration in atomic purcent were determined by chemical analyzes (proton or electron induced X-ray emission) and from the depo-sition rate of each species. We control the alloy-ing through the increase of the resistivity as the