Modulating Exchange Bias, Anisotropic Magnetoresistance, and Planar Hall Resistance of Flexible Co/MnN Epitaxial Bilayers on Mica by Bending Strain.

The integration of ferromagnetic/antiferromagnetic bilayers with exchange bias effect on flexible substrates is crucial for flexible spintronics. Here, the epitaxial Co/MnN bilayers are deposited on mica by facing-target sputtering. A large in-plane exchange bias field ( H EB ) of 1800 Oe with a coercive field ( H C ) of 2750 Oe appears in the Co (3.8 nm)/MnN (15.0 nm) bilayer at 5 K after field cooling from 300 to 5 K. Effective interfacial exchange energy J eff of the Co/MnN bilayer is 0.83 erg/cm 2 . The strain-induced maximum increase of H EB and H C reaches 18% and 21%, respectively, in the Co(3.8 nm)/MnN(15.0 nm) bilayer. Strain-modulated H EB is attributed to the change of interfacial exchange coupling between Co and MnN layers. H EB is inversely proportional to Co thickness but independent of MnN thickness. The change of H EB is less than 5% after 100 bending cycles, indicating mechanical durability. The out-of-plane exchange bias also appears since Co spins are not fully reversed due to the strong pinning effect. Anisotropic magnetoresistance (AMR) and planar Hall resistance ( R xy ) show obvious hysteresis due to H EB . Exchange bias-induced phase difference of AMR and R xy almost remains unchanged at different bending strains. The results provide the basis for understanding the bending strain tailored exchange bias.