Path to Overcome Material and Fundamental Obstacles in Spin Valves Based on MoS 2 and Other Transition-Metal Dichalcogenides

Experimental studies on spin valves with exfoliated 2D materials face the main technological issue of ferromagnetic electrode oxidation during the 2Ds integration process. As a twofold outcome, magne-toresistance (MR) signals are very difficult to obtain and, when they finally are, they are often fa...

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Veröffentlicht in:	Physical review applied 2019, Vol.12 (4)
Hauptverfasser:	Galbiati, Marta, Tatay, Sergio, Dubois, Simon M.-M, Godel, Florian, Galceran, Regina, Mañas-Valero, Samuel, Piquemal-Banci, Maëlis, Vecchiola, Aymeric, Charlier, Jean-Christophe, Forment-Aliaga, Alicia, Coronado, Eugenio, Dlubak, Bruno, Seneor, Pierre
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Schlagworte:	Condensed Matter Materials Science Physics
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creator	Galbiati, Marta Tatay, Sergio Dubois, Simon M.-M Godel, Florian Galceran, Regina Mañas-Valero, Samuel Piquemal-Banci, Maëlis Vecchiola, Aymeric Charlier, Jean-Christophe Forment-Aliaga, Alicia Coronado, Eugenio Dlubak, Bruno Seneor, Pierre
description	Experimental studies on spin valves with exfoliated 2D materials face the main technological issue of ferromagnetic electrode oxidation during the 2Ds integration process. As a twofold outcome, magne-toresistance (MR) signals are very difficult to obtain and, when they finally are, they are often far from expectations. We propose a fabrication method to circumvent this key issue for 2D-based spintronics devices. We report on the fabrication of NiFe/MoS 2 /Co spin valves with mechanically exfoliated mul-tilayer MoS 2 using an in situ fabrication protocol that allows high-quality nonoxidized interfaces to be maintained between the ferromagnetic electrodes and the 2D layer. Devices display a large MR of 5%. Beyond interfaces and material quality, we suggest that an overlooked more fundamental physics issue related to spin-current depolarization could explain the limited MR observed so far in MoS 2-based magnetic tunnel junctions. This points to a path towards the observation of larger spin signals in line with theoretical predictions above 100%. We envision the impact of our work to be beyond MoS 2 and its broader transition-metal dichalcogenides family by opening the way to an accelerated screening of other 2D materials that are yet to be explored for spintronics.
doi_str_mv	10.1103/PhysRevApplied.12.044022
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title	Path to Overcome Material and Fundamental Obstacles in Spin Valves Based on MoS 2 and Other Transition-Metal Dichalcogenides
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