Your search keyword '"Rojas-Sanchez JC"' showing total 4 results

1. Spin–orbit torque switching of a ferromagnet with picosecond electrical pulses

Author

Jhuria, K, Jhuria, K, Hohlfeld, J, Pattabi, A, Martin, E, Arriola Córdova, AY, Shi, X, Lo Conte, R, Petit-Watelot, S, Rojas-Sanchez, JC, Malinowski, G, Mangin, S, Lemaître, A, Hehn, M, Bokor, J, Wilson, RB, Gorchon, J, Jhuria, K, Jhuria, K, Hohlfeld, J, Pattabi, A, Martin, E, Arriola Córdova, AY, Shi, X, Lo Conte, R, Petit-Watelot, S, Rojas-Sanchez, JC, Malinowski, G, Mangin, S, Lemaître, A, Hehn, M, Bokor, J, Wilson, RB, and Gorchon, J

Abstract

The development of approaches that can efficiently control the magnetization of magnetic materials is central to the creation of fast and low-power spintronic devices. Spin transfer torque can be used to electrically manipulate magnetic order in devices, but is typically limited to nanosecond timescales. Alternatively, spin–orbit torque can be employed, and switching with current pulses down to ~200 ps has been demonstrated. However, the upper limit to magnetization switching speed remains unestablished. Here, we show that photoconductive switches can be used to apply 6-ps-wide electrical pulses and deterministically switch the out-of-plane magnetization of a common thin cobalt film via spin–orbit torque. We probe the ultrafast magnetization dynamics due to spin–orbit torques with sub-picosecond resolution using the time-resolved magneto-optical Kerr effect (MOKE). We also estimate that the magnetization switching consumes less than 50 pJ in micrometre-sized devices.

Published

2020

2. Evidence of Pure Spin-Current Generated by Spin Pumping in Interface-Localized States in Hybrid Metal-Silicon-Metal Vertical Structures.

Author

Cerqueira C, Qin JY, Dang H, Djeffal A, Le Breton JC, Hehn M, Rojas-Sanchez JC, Devaux X, Suire S, Migot S, Schieffer P, Mussot JG, Łaczkowski P, Anane A, Petit-Watelot S, Stoffel M, Mangin S, Liu Z, Cheng BW, Han XF, Jaffrès H, George JM, and Lu Y

Abstract

Due to the difficulty of growing high-quality semiconductors on ferromagnetic metals, the study of spin diffusion transport in Si was limited to lateral geometry devices. In this work, by using an ultrahigh-vacuum wafer-bonding technique, we have successfully fabricated metal-semiconductor-metal CoFeB/MgO/Si/Pt vertical structures. We hereby demonstrate pure spin-current injection and transport in the perpendicular current flow geometry over a distance larger than 2 μm in n-type Si at room temperature. In those experiments, a pure propagating spin current is generated via ferromagnetic resonance spin pumping and converted into a measurable voltage by using the inverse spin Hall effect occurring in the top Pt layer. A systematic study varying both Si and MgO thicknesses reveals the important role played by the localized states at the MgO-Si interface for the spin-current generation. Proximity effects involving indirect exchange interactions between the ferromagnet and the MgO-Si interface states appears to be a prerequisite to establishing the necessary out-of-equilibrium spin population in Si under the spin-pumping action.

Published

2019

3. Switchable spin-current source controlled by magnetic domain walls.

Author

Savero Torres W, Laczkowski P, Nguyen VD, Rojas Sanchez JC, Vila L, Marty A, Jamet M, and Attané JP

Abstract

Using nonlocal spin injection, spin-orbit coupling, or spincaloritronic effects, the manipulation of pure spin currents in nanostructures underlies the development of new spintronic devices. Here, we demonstrate the possibility to create switchable pure spin current sources, controlled by magnetic domain walls. When the domain wall is located at a given point of the magnetic circuit, a pure spin current is injected into a nonmagnetic wire. Using the reciprocal measurement configuration, we demonstrate that the proposed device can also be used as a pure spin current detector. Thanks to its simple geometry, this device can be easily implemented in spintronics applications; in particular, a single current source can be used both to induce the domain wall motion and to generate the spin signal.

Published

2014

4. Crossover from spin accumulation into interface states to spin injection in the germanium conduction band.

Author

Jain A, Rojas-Sanchez JC, Cubukcu M, Peiro J, Le Breton JC, Prestat E, Vergnaud C, Louahadj L, Portemont C, Ducruet C, Baltz V, Barski A, Bayle-Guillemaud P, Vila L, Attané JP, Augendre E, Desfonds G, Gambarelli S, Jaffrès H, George JM, and Jamet M

Abstract

Electrical spin injection into semiconductors paves the way for exploring new phenomena in the area of spin physics and new generations of spintronic devices. However the exact role of interface states in the spin injection mechanism from a magnetic tunnel junction into a semiconductor is still under debate. In this Letter, we demonstrate a clear transition from spin accumulation into interface states to spin injection in the conduction band of n-Ge. We observe spin signal amplification at low temperature due to spin accumulation into interface states followed by a clear transition towards spin injection in the conduction band from 200 K up to room temperature. In this regime, the spin signal is reduced to a value compatible with the spin diffusion model. More interestingly, the observation in this regime of inverse spin Hall effect in germanium generated by spin pumping and the modulation of the spin signal by a gate voltage clearly demonstrate spin accumulation in the germanium conduction band.

Published

2012