Sub-nanometer Atomic Layer Deposition for Spintronics in Magnetic Tunnel Junctions Based on Graphene Spin-Filtering Membranes
Citations Over TimeTop 10% of 2014 papers
Abstract
We report on the successful integration of low-cost, conformal, and versatile atomic layer deposited (ALD) dielectric in Ni–Al2O3–Co magnetic tunnel junctions (MTJs) where the Ni is coated with a spin-filtering graphene membrane. The ALD tunnel barriers, as thin as 0.6 nm, are grown layer-by-layer in a simple, low-vacuum, ozone-based process, which yields high-quality electron-transport barriers as revealed by tunneling characterization. Even under these relaxed conditions, including air exposure of the interfaces, a significant tunnel magnetoresistance is measured highlighting the robustness of the process. The spin-filtering effect of graphene is enhanced, leading to an almost fully inversed spin polarization for the Ni electrode of −42%. This unlocks the potential of ALD for spintronics with conformal, layer-by-layer control of tunnel barriers in magnetic tunnel junctions toward low-cost fabrication and down-scaling of tunnel resistances.
Related Papers
- → Spin-guide source for the generation of highly spin-polarized currents(2003)17 cited
- → Tunnel magnetoresistance in alumina, magnesia and composite tunnel barrier magnetic tunnel junctions(2011)5 cited
- → Tunnel magnetoresistance on ferromagnetic single-electron transistors with multiple tunnel junction(2001)13 cited
- → Dependences of the Tunnel Magnetoresistance and Spin Transfer Torque on the Sizes and Concentration of Nanoparticles in Magnetic Tunnel Junctions(2018)1 cited
- → Magnetic switching and magnetoresistance in nanoscale spin tunnel junctions(2002)6 cited