Tool for annealing of magnetic stacks

The invention claimed is: 1. A tool for annealing a magnetic stack, the tool comprising: a housing defining a heating chamber; a holding mechanism configured to hold a wafer within the heating chamber; a heating mechanism configured to heat the wafer; and a magnetic field generator including a plurality of elongated, parallel, current-carrying conductors that traverse a major surface of the wafer and generate a magnetic field whose magnetic field lines pass through the wafer and align a magnetic domain in the wafer in a direction that is parallel with the major surface of the wafer. 2. The tool of claim 1 , wherein the heating mechanism comprises a grid of resistive conductors disposed along first and second directions. 3. The tool of claim 2 , wherein the grid is configured to supply heat directly to the wafer. 4. The tool of claim 2 , wherein the grid is configured to heat a heating block which in turn transfers heat to the wafer. 5. The tool of claim 2 , wherein the grid and the magnetic field generator are disposed to sandwich the wafer between them. 6. The tool of claim 1 , wherein the tool is a retrofitted thermal processor for a semiconductor wafer processor. 7. The tool of claim 6 , wherein the retrofitted thermal processor is a rapid thermal processor. 8. A tool for annealing a magnetic stack, the tool comprising: a housing defining a heating chamber; a holding mechanism configured to hold a plurality of wafers in a single line within the heating chamber; a heating mechanism including a grid of resistive conductors configured to heat the plurality of wafers; and a magnetic field generator including a plurality of elongated, parallel, current-carrying conductors that traverse a major surface of each wafer of the plurality of wafers and generate, during a magnetic annealing process, a magnetic field whose magnetic field lines pass through the plurality of wafers and align a magnetic domain in each wafer of the plurality of wafers in a direction parallel with its respective major surface; wherein the heating mechanism and the magnetic field generator are configured to sandwich the plurality of wafers between them. 9. The tool of claim 8 , wherein the grid of resistive conductors are disposed along first and second directions. 10. The tool of claim 8 , wherein the grid is configured to heat one or more heating blocks which in turn transfer heat to the plurality of wafers. 11. The tool of claim 8 , wherein the heating chamber comprises a plurality of opaque quartz insulating walls. 12. The tool of claim 11 , wherein the plurality of opaque quartz insulating walls comprise a glazed surface. 13. The tool of claim 8 , further comprising: a plurality of pins mounted to a pin support plate, wherein the plurality of pins are configured to receive and support a wafer including the magnetic stack; and a lift configured to lower the pin support plate and the plurality of pins to place the wafer in close proximity to the heating mechanism. 14. The tool of claim 8 , further comprising: a heated block having a greater thermal mass than a wafer including the magnetic stack; a plurality of pins extending through the heated block and mounted to a pin support plate, wherein the plurality of pins are configured to receive and support the wafer; and a lift configured to lower the pin support plate and the plurality of pins to place the wafer in close proximity to the heated block. 15. The tool of claim 8 , further comprising an outer housing that defines an insulating chamber between walls of the heating chamber and the outer housing. 16. The tool of claim 8 , wherein the heating chamber comprises a gas inlet and a gas outlet via which pressure within the heating chamber is configured to be controlled. 17. The tool of claim 8 , wherein the grid of resistive conductors is configured to directly heat the plurality of wafers. 18. A tool for annealing a magnetic stack of a wafer, the tool comprising: a housing defining a heating chamber; a holding mechanism configured to hold the wafer within the heating chamber; a heating mechanism configured to heat the wafer; and a magnetic field generator including a plurality of elongated, parallel, current-carrying conductors that traverse a major surface of the wafer and generate a magnetic field whose magnetic field lines pass through the wafer and provide a pinning layer of the magnetic stack with a common magnetic domain aligned in a direction parallel with the major surface of the wafer. 19. The tool of claim 18 , wherein the heating mechanism comprises a grid of resistive conductors that are disposed along first and second directions and that are configured to supply heat directly to the wafer. 20. The tool of claim 19 , further comprising: a heating block positioned to transfer heat to the wafer; wherein the grid is configured to heat the heating block which in turn transfers heat to the wafer.