Octupole-driven spin-transfer torque switching of all-antiferromagnetic tunnel junctions
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Magnetic tunnel junctions (MTJs) based on ferromagnets are canonical devices in spintronics, with wide-ranging applications in data storage, computing, and sensing. They simultaneously exhibit mechanisms for electrical detection of magnetic order through the tunneling magnetoresistance (TMR) effect, and reciprocally, for controlling magnetic order by electric currents through spin-transfer torque (STT). It was long assumed that neither of these effects could be sizeable in tunnel junctions made from antiferromagnetic materials, since they exhibit no net magnetization. Recently, however, it was shown that all-antiferromagnetic tunnel junctions (AFMTJs) based on chiral antiferromagnets do exhibit TMR due to their non-relativistic momentum-dependent spin polarization and cluster magnetic octupole moment, which are manifestations of their spin-split band structure. However, the reciprocal effect, i.e., the antiferromagnetic counterpart of STT driven by currents through the AFMTJ, has been assumed non-existent due to the total electric current being spin-neutral. Here, in contrast to this common expectation, we report nanoscale AFMTJs exhibiting this reciprocal effect, which we term octupole-driven spin-transfer torque (OTT). We demonstrate current-induced OTT switching of PtMn3|MgO|PtMn3 AFMTJs, fabricated on a thermally oxidized silicon substrate, exhibiting a record-high TMR value of 363% at room temperature and switching current densities of the order of 10 MA/cm2. Our theoretical modeling explains the origin of OTT in terms of the imbalance between intra- and inter-sublattice spin currents across the AFMTJ, and equivalently, in terms of the non-zero net cluster octupole polarization of each PtMn3 layer. This work establishes a new materials platform for antiferromagnetic spintronics and provides a pathway towards deeply scaled magnetic memory and room-temperature terahertz technologies.
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