Abstract
The manipulation of antiferromagnetic order in magnetoelectric Cr2O3 using electric field has been of great interest due to its potential in low-power electronics. The substantial leakage and low dielectric breakdown observed in twinned Cr2O3 thin films, however, hinders its development in energy efficient spintronics. To compensate, large film thicknesses (250 nm or greater) have been employed at the expense of device scalability. Recently, epitaxial V2O3 thin film electrodes have been used to eliminate twin boundaries and significantly reduce the leakage of 300 nm thick single crystal films. Here we report the electrical endurance and magnetic properties of thin (less than 100 nm) single crystal Cr2O3 films on epitaxial V2O3 buffered Al2O3 (0001) single crystal substrates. The growth of Cr2O3 on isostructural V2O3 thin film electrodes helps eliminate the existence of twin domains in Cr2O3 films, therefore significantly reducing leakage current and increasing dielectric breakdown. 60 nm thick Cr2O3 films show bulk-like resistivity (~ 1012 Ω cm) with a breakdown voltage in the range of 150–300 MV/m. Exchange bias measurements of 30 nm thick Cr2O3 display a blocking temperature of ~ 285 K while room temperature optical second harmonic generation measurements possess the symmetry consistent with bulk magnetic order.
Highlights
The manipulation of antiferromagnetic order in magnetoelectric Cr2O3 using electric field has been of great interest due to its potential in low-power electronics
One issue hindering electric field manipulation of magnetic order in thin film Cr2O3 is the existence of twin domain boundaries that result from the growth on elemental metal electrodes, in films below 250 nm[12] which are necessary for technological adoption
Investigation of the magnetic properties of single crystal Cr2O3 thin films using an exchange coupled ferromagnetic layer and optical second harmonic generation indicates bulk like behavior around room temperature in films at 30 nm thickness
Summary
The manipulation of antiferromagnetic order in magnetoelectric Cr2O3 using electric field has been of great interest due to its potential in low-power electronics. The growth of Cr2O3 on isostructural V2O3 thin film electrodes helps eliminate the existence of twin domains in Cr2O3 films, significantly reducing leakage current and increasing dielectric breakdown. The relatively conductive twin boundaries lead to high leakage current and reduce dielectric breakdown voltage down below the critical magnetoelectric switching voltage In previous reports, this issue has been circumvented by utilizing C r2O3 films of large thickness[12,16] but at proposed device scales this is not a viable solution. Investigation of the magnetic properties of single crystal Cr2O3 thin films using an exchange coupled ferromagnetic layer and optical second harmonic generation indicates bulk like behavior around room temperature in films at 30 nm thickness
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