Systematic investigation of the effect of layer thickness on the linear sensing characteristics of asymmetric structured CoFe/Rh/CoFe/Cu/CoFe fully epitaxial CIP-GMR based magnetic sensors.

• CoFe/Rh/CoFe/bcc-Cu/CoFe based epitaxial current-in-plane -GMR devices were fabricated. • The effect of CoFe and Rh thicknesses on the nature of magnetic couplings was studied. • Numerical simulation confirmed both biquadratic and bilinear couplings, offering linear MR. • CIP-GMR devices with the asymmetric structure are promising for the next generation linear magnetic sensors. Giant magnetoresistance (GMR) devices known for their widespread application as magnetic field sensors face challenges owing to their nonlinear resistance response with the magnetic field. Here, we have developed CoFe(3 nm)/Rh(t R h nm)/CoFe(t m i d C o F e nm)/bcc Cu(1.6 nm)/CoFe(t t o p C o F e nm)/MgO(2 nm) based current in plane (CIP)-GMR devices and demonstrated linear MR curves with tunable characteristics. The MR ratio and saturating magnetic field were tunable between 3.9% and 23.5%, and 0.013 T and 1.5 T. The numerical simulation modeling confirmed biquadratic coupling between the bottom and middle CoFe layers through Rh and antiferromagnetic coupling between the middle and top CoFe layers through a Cu spacer, providing the linear MR. The fine-tuning of thicknesses of the middle and top CoFe layers provides supplementary routes for optimizing the sensitivity and operation field range of the CIP-GMR devices to specific magnetic sensor applications in the low and medium magnetic field range. The above results demonstrate that CIP-GMR devices with the asymmetric structure demonstrated in this study are promising for the next generation linear magnetic sensors. [ABSTRACT FROM AUTHOR]