초록 ▼

The present invention provides a spin-valve magnetoresistive sensor comprising at least two ferromagnetic layers including a first and a second ferromagnetic layers. A first antiferromagnetic layer is layered adjacent to the first ferromagnetic layer for increasing the coercive force of the first fe

The present invention provides a spin-valve magnetoresistive sensor comprising at least two ferromagnetic layers including a first and a second ferromagnetic layers. A first antiferromagnetic layer is layered adjacent to the first ferromagnetic layer for increasing the coercive force of the first ferromagnetic layer to pin the magnetization direction of the first ferromagnetic layer. A pair of second antiferromagnetic layers are respectively positioned adjacent to the longitudinal ends of the second ferromagnetic layer. Further, a pair of third ferromagnetic layers are respectively layered adjacent to said pair of second antiferromagnetic layers for inducing magnetic anisotropy to pin the magnetization direction of each third ferromagnetic layer in a direction perpendicular to the pinned magnetization direction of the first ferromagnetic layer, thereby imposing a longitudinal bias on the second ferromagnetic layer to stabilize magnetic domains therein in order to suppress Barkhausen noise. The magnetization direction of the second ferromagnetic layer remains free to rotate in accordance with the direction of an external magnetic field, thereby changing the electrical resistance of the sensor.

대표청구항 ▼

1. A spin-valve magnetoresistive sensor comprising:(a) at least two ferromagnetic layers layered with a non-magnetic layer sandwiched therebetween, said at least two ferromagnetic layers including a first and a second ferromagnetic layers, said second ferromagnetic layer including a magnetic sensing

1. A spin-valve magnetoresistive sensor comprising:(a) at least two ferromagnetic layers layered with a non-magnetic layer sandwiched therebetween, said at least two ferromagnetic layers including a first and a second ferromagnetic layers, said second ferromagnetic layer including a magnetic sensing region located midway along its longitudinal length, said magnetic sensing region being substantially equal in longitudinal length to a track width; (b) a first antiferromagnetic layer layered adjacent to said first ferromagnetic layer for increasing the coercive force of said first ferromagnetic layer to pin the magnetization direction of said first ferromagnetic layer; (c) a pair of second antiferromagnetic layers respectively layered adjacent to said second ferromagnetic layer on each longitudinal side of said magnetic sensing region for inducing magnetic anisotropy directly in said second ferromagnetic layer to pin the magnetization directions in said second ferromagnetic layer on each longitudinal side of said magnetic sensing region in a direction perpendicular to the pinned magnetization direction of said first ferromagnetic layer, thereby imposing a longitudinal bias on the magnetic sensing region to stabilize magnetic domains in said magnetic sensing region and orient the magnetization direction of said magnetic sensing region perpendicular to the pinned magnetization direction of said first ferromagnetic layer in the absence of any external magnetic field, whereas, in the presence of an external magnetic field, permitting the magnetization direction of said magnetic sensing region to freely rotate to the direction of said external magnetic field, wherein (e) said first antiferromagnetic layer is made of .alpha.-Fe2O3, and (f) said pair of second antiferromagnetic layers are made of an X-Mn system alloy having a disordered structure where said X is made of at least one metal selected from the group consisting of Pt, Pd, Ir, Ru or Rh.