Dual free layer magnetic reader having a rear bias structure having a high aspect ratio

We claim: 1. A magnetic read apparatus having an air-bearing surface (ABS), the magnetic read apparatus comprising: a read sensor comprising a first free layer, a spacer layer, and a second free layer, the spacer layer being nonmagnetic and residing between the first free layer and the second free layer, the read sensor having a rear surface opposite to the ABS, at least one side surface and a track width in a cross-track direction; a rear magnetic bias structure configured to magnetically bias the read sensor in a stripe height direction perpendicular to the ABS, the read sensor being between the ABS and the rear magnetic bias structure, the rear magnetic bias structure having a width in the cross-track direction and a length in the stripe height direction, the length being greater than the width, the width of the rear magnetic bias structure being substantially equal to the track width of the read sensor, the rear magnetic bias structure including a rear hard magnetic bias structure having a hard bias coercivity of greater than one hundred Oersted; an insulating layer between the read sensor and the rear hard magnetic bias structure; and a side magnetic bias structure adjacent to each of the at least one side surface, the side magnetic bias structure comprising a first magnetic bias structure adjacent to a side surface of the first free layer in the cross-track direction and a second magnetic bias structure adjacent to a side surface of the second free layer in the cross-track direction, wherein the first magnetic bias structure and the second magnetic bias structure are separated by a non-magnetic structure. 2. The magnetic read apparatus of claim 1 wherein the rear magnetic bias structure has a reversal field of at least one thousand Oersted. 3. The magnetic read apparatus of claim 2 wherein the reversal field is at least five thousand Oersted. 4. The magnetic read apparatus of claim 1 wherein the track width of the read sensor is not more than thirty nanometers. 5. The magnetic read apparatus of claim 4 wherein the track width of the read sensor is not more than twenty nanometers. 6. The magnetic read apparatus of claim 1 wherein the hard bias coercivity is greater than one thousand Oersted. 7. The magnetic read apparatus of claim 1 wherein the rear magnetic bias structure includes: a pinning layer coupled to the rear hard bias structure. 8. The magnetic read apparatus of claim 1 wherein the side magnetic bias structure is configured to magnetically bias the first free layer and the second free layer to be antiferromagnetically aligned, and wherein the first magnetic bias structure and the second magnetic bias structure are antiferromagnetically aligned. 9. The magnetic read apparatus of claim 1 wherein the length of the rear magnetic bias structure is at least four times the width. 10. The magnetic read apparatus of claim 9 wherein the length of the rear magnetic bias structure is at least ten times the width. 11. The magnetic read apparatus of claim 1 further comprising an additional insulating layer between the side magnetic bias structure and the read sensor. 12. The magnetic read apparatus of claim 1 , wherein the rear hard magnetic bias structure is conductive. 13. The magnetic read apparatus of claim 1 , wherein the insulating layer includes: a first surface between the read sensor and the rear magnetic bias structure, and a second surface along the stripe height direction on a side of the rear magnetic bias structure, one end of the second surface coupled to the first surface. 14. A disk drive comprising: at least one slider comprising at least one magnetic transducer having an air-bearing surface (ABS), the at least one magnetic transducer comprising a read sensor and a rear magnetic bias structure, the read sensor comprising a first free layer, a spacer layer, and a second free layer, the spacer layer being nonmagnetic and residing between the first free layer and the second free layer, the read sensor having a rear surface opposite to the ABS, at least one side surface and a track width in a cross-track direction, the rear magnetic bias structure being configured to provide a magnetic bias to the read sensor in a stripe height direction perpendicular to the ABS, the read sensor being between the ABS and the rear magnetic bias structure, the rear magnetic bias structure having a width in the cross-track direction and a length in the stripe height direction, the length being greater than the width, the width of the rear magnetic bias structure being substantially equal to the track width of the read sensor, the rear magnetic bias structure including a rear hard magnetic bias structure having a hard bias coercivity of greater than one hundred Oersted, the at least one magnetic transducer further comprising an insulating layer between the read sensor and the rear hard magnetic bias structure, and a side magnetic bias structure adjacent to each of the at least one side surface, the side magnetic bias structure comprising a first magnetic bias structure adjacent to a side surface of the first free layer in the cross-track direction and a second magnetic bias structure adjacent to a side surface of the second free layer in the cross-track direction, wherein the first magnetic bias structure and the second magnetic bias structure are separated by a non-magnetic structure. 15. The disk drive of claim 14 , wherein the rear hard magnetic bias structure is conductive. 16. A magnetic read apparatus having an air-bearing surface (ABS), the magnetic read apparatus comprising: a read sensor comprising a first free layer, a spacer layer, and a second free layer stacked in a first direction, the spacer layer being nonmagnetic and disposed between the first free layer and the second free layer, the read sensor having a rear surface opposite to the ABS; a rear magnetic bias structure coupled to the rear surface of the read sensor, the rear magnetic bias structure configured to magnetically bias the read sensor in a second direction perpendicular to the ABS, the read sensor disposed between the ABS and the rear magnetic bias structure, the rear magnetic bias structure having a hard bias coercivity of greater than one hundred Oersted, the rear magnetic bias structure having a width along a third direction and a length along the second direction, the length being greater than the width; an insulating layer between the read sensor and the rear magnetic bias structure having the hard bias coercivity of greater than one hundred Oersted; and a side magnetic bias structure on a side surface of the read sensor, the side surface of the read sensor facing in the third direction, the side magnetic bias structure comprising a first side magnetic bias structure to magnetically bias the first free layer and a second side magnetic bias structure to magnetically bias the second free layer. 17. The magnetic read apparatus of claim 16 , wherein the rear magnetic bias structure is conductive. 18. The magnetic read apparatus of claim 16 , wherein the insulating layer includes: a first surface between the read sensor and the rear magnetic bias structure, and a second surface along the second direction on a side of the rear magnetic bias structure, one end of the second surface coupled to the first surface.