Tunneling magnetoresistance in magnetic tunnel junctions with a single ferromagnetic electrode
Abstract
Magnetic tunnel junctions (MTJs) are key components of spintronic devices, such as magnetic random-access memories. Normally, MTJs consist of two ferromagnetic (FM) electrodes separated by an insulating barrier layer. Their key functional property is tunneling magnetoresistance (TMR) that is a change in MTJ's resistance when magnetization of the two electrodes alters from parallel to antiparallel. Here, we demonstrate that TMR can occur in MTJs with a single FM electrode, provided that the counter electrode is an antiferromagnetic (AFM) metal that supports a spin-split band structure and/or a N\'eel spin current. Using RuO2 as a representative example of such antiferromagnet and CrO2 as a FM metal, we design all-rutile RuO2/TiO2/CrO2 MTJs to reveal a non-vanishing TMR. Our first-principles calculations predict that magnetization reversal in CrO2 significantly changes conductance of the MTJs stacked in the (110) or (001) planes. The predicted giant TMR effect of about 1000% in the (110) oriented MTJs stems from spin-dependent conduction channels in CrO2 (110) and RuO2 (110), whose matching alters with CrO2 magnetization orientation, while TMR in the (001) oriented MTJs originates from the N\'eel spin currents and different effective TiO2 barrier thickness for the two magnetic sublattices that can be engineered by the alternating deposition of TiO2 and CrO2 monolayers. Our results demonstrate a possibility of a sizable TMR in MTJs with a single FM electrode and offer a practical test for using the altermagnet RuO2 in functional spintronic devices.
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