Spin-signal enhancement in a lateral spin valve reader

What is claimed is: 1. A lateral spin valve reader comprising: a detector structure having a surface that forms a portion of a bearing surface; a first shield in contact with the detector structure; a spin injection structure located away from the bearing surface; a second shield in contact with the spine injection structure; a channel layer extending from the detector structure to the spin injection structure; a tunnel barrier layer between at least one of the detector structure and the channel layer or the spin injection structure and the channel layer; and an exterior cladding, disposed around the channel layer, configured to suppress spin-scattering at surfaces of the channel layer, wherein a thickness of the exterior cladding relative to the channel layer is between about 2.5 nanometers and about 20 nanometers, and wherein a thickness of the tunnel barrier layer is less than the thickness of the exterior cladding. 2. The lateral spin valve reader of claim 1 and wherein the exterior cladding comprises an insulator. 3. The lateral spin valve reader of claim 2 and wherein the insulator is a high dielectric constant insulator selected from the group consisting of Al 2 O 3 , HfO 2 , TiO 2 , ZrO 2 , Si 3 N 4 , Ta 2 O 5 , one or more Titanates and combinations thereof. 4. The lateral spin valve reader of claim 3 and wherein the one or more Titanates comprise BaTiO 3 and SrTiO 3 . 5. The lateral spin valve reader of claim 1 and wherein the exterior cladding comprises a semiconductor. 6. The lateral spin valve reader of claim 5 and wherein the semiconductor is selected from the group consisting of AlN, alloys comprising AlN, GaN, alloys comprising GaN, GaAs, alloys comprising GaAs, ZnO, alloys comprising ZnO, Diamond and combinations thereof. 7. The lateral spin valve reader of claim 1 and wherein the thickness of the tunnel barrier layer is less than or equal to about 1.5 nanometers. 8. The lateral spin valve reader of claim 1 and wherein the tunnel barrier layer is formed of a first material and the exterior cladding is formed of a second material that is different from the first material. 9. The lateral spin valve reader of claim 1 and wherein the tunnel barrier layer and the exterior cladding are formed of a same material. 10. The lateral spin valve reader of claim 1 and wherein the exterior cladding comprises a bilayer including a first layer comprising a first dielectric material and a second layer comprising a second dielectric material that is different from the first dielectric material. 11. The lateral spin valve reader of claim 5 and wherein the exterior cladding comprises a semiconductor material having an energy gap that is greater than or equal to about one electron volt. 12. The lateral spin valve reader of claim 2 and wherein the exterior cladding comprises an insulator material having an energy gap that is greater than or equal to about three electron volts. 13. The lateral spin valve reader of claim 1 and wherein the exterior cladding comprises a material having a dielectric constant that is greater than twice a permittivity of free space. 14. A lateral spin valve reader comprising: a detector structure having a surface that forms a portion of a bearing surface; a first shield in contact with the detector structure; a spin injection structure located away from the bearing surface; a second shield in contact with the spine injection structure; a channel layer extending from the detector structure to the spin injection structure; a tunnel barrier layer between at least one of the detector structure and the channel layer or the spin injection structure and the channel layer; and an exterior cladding, disposed around the channel layer, configured to suppress spin-scattering at surfaces of the channel layer, wherein the exterior cladding comprises a semiconductor, and wherein a thickness of the tunnel barrier layer is less than a thickness of the exterior cladding relative to the channel layer. 15. The lateral spin valve reader of claim 14 and wherein the semiconductor is selected from the group consisting of AlN, alloys comprising AlN, GaN, alloys comprising GaN, GaAs, alloys comprising GaAs, ZnO, alloys comprising ZnO, Diamond and combinations thereof. 16. The lateral spin valve reader of claim 14 and wherein the exterior cladding comprises a semiconductor material having an energy gap that is greater than or equal to about one electron volt. 17. A method of forming a recording head comprising: providing a substrate; forming a bottom shield over the substrate; forming an injector structure and a first portion of a cladding over the bottom shield, wherein the injector structure is in contact with the bottom shield; forming a channel layer over the injector structure and over the first portion of the cladding; forming a second portion of the cladding on sides of the channel layer; forming a detector structure and a third portion of the cladding over the channel layer such that the first portion of the cladding, the second portion of the cladding and the third portion of the cladding surround the channel layer, wherein the detector structure includes a surface that forms a portion of a bearing surface of the recording head; forming a top shield over the detector structure, wherein the top shield is in contact with the detector structure; forming a tunnel barrier layer between at least one of the detector structure and the channel layer or the injector structure and the channel layer, wherein a thickness of the cladding relative to the channel layer is between about 2.5 nanometers and about 20 nanometers, and wherein a thickness of the tunnel barrier layer is less than the thickness of the cladding. 18. The method of claim 17 and wherein the cladding comprises a material having an energy gap that is greater than three electron volts. 19. The method of claim 17 and wherein the cladding comprises a material having a dielectric constant that is greater than twice a permittivity of free space.