Iridium underlayer for heat assisted magnetic recording media

What is claimed is: 1. A heat-assisted magnetic recording medium, comprising: a substrate; an adhesion layer deposited over the substrate; a heat sink layer deposited over the adhesion layer; a first underlayer deposited over the heat sink layer, the first underlayer comprising a body-centered-cubic Co-based material or a body-centered cubic CoFe-based material; a second underlayer deposited directly over the first underlayer, the second underlayer comprising an Ir-based material; and a magnetic recording layer for storing data via heat-assisted magnetic recording deposited over the second underlayer. 2. The heat-assisted magnetic recording medium of claim 1 , further comprising an overcoat layer disposed over the magnetic recording layer. 3. The heat-assisted magnetic recording medium of claim 2 , wherein the overcoat layer comprises one of hydrogenated or nitrogenated carbon. 4. The heat-assisted magnetic recording medium of claim 1 , wherein the first underlayer includes an additive comprising at least one of Ni, Zr, B, Ta, W, or Mo. 5. The heat-assisted magnetic recording medium of claim 1 , wherein the heat sink layer comprises (002) Tungsten (W), (002) Ruthenium Aluminide (RuAl), and amorphous Chromium Tantalum (CrTa). 6. The heat-assisted magnetic recording medium of claim 1 , wherein the adhesion layer comprises amorphous Nickel-Tantalum (Ni—Ta). 7. The heat-assisted magnetic recording medium of claim 1 , wherein the substrate comprises one of a glass, metallic, polymer, or ceramic material capable of withstanding temperatures of at least approximately 400° C.-750° C. 8. The heat-assisted magnetic recording medium of claim 1 , wherein the magnetic recording layer is an alloy comprising (001) Iron-Platinum (FePt). 9. The heat-assisted magnetic recording medium of claim 1 , wherein the Ir-based material comprises one of pure Ir, an Ir-based alloy, an Ir-based compound, and a granular Ir layer with segregants. 10. The heat-assisted magnetic recording medium of claim 9 , wherein the Ir-based alloy comprises one of an Iridium Titanium (IrTi) alloy, an Iridium Zirconium (IrZr) alloy, or an Iridium Carbon (IrC) alloy. 11. The heat-assisted magnetic recording medium of claim 9 , wherein the segregants comprise at least one of light and heat absorbing materials. 12. A method, comprising: generating or providing a substrate; depositing an adhesion layer over the substrate; depositing a heat sink layer over the adhesion layer; depositing a first underlayer over the heat sink layer, the first underlayer comprising a body-centered-cubic Co-based material or a body-centered cubic CoFe-based material; depositing a second underlayer directly over the first underlayer, the second underlayer comprising an or Ir-based material; and depositing a recording layer over the second underlayer. 13. The method of claim 12 , wherein the substrate comprises one of a glass, metallic, polymer, or ceramic material capable of withstanding temperatures of at least approximately 400° C.-750° C. 14. The method of claim 12 , wherein the adhesion layer comprises amorphous Nickel-Tantalum (Ni—Ta), and wherein the heat sink layer comprises (002) Tungsten (W), (002) Ruthenium Aluminide (RuAl), and amorphous Chromium Tantalum (CrTa). 15. The method of claim 12 , wherein the recording layer is a heat-assisted magnetic recording (HAMR) recording layer. 16. The method of claim 12 , wherein the recording layer is an alloy comprising (001) Iron-Platinum (FePt). 17. The method of claim 16 , wherein the (001) Iron-Platinum (FePt) alloy comprises a (001) Iron-Platinum (FePt) film having at least a 98 percent correct grain orientation structure. 18. The method of claim 12 , wherein the Ir-based material comprises one of an Ir-based alloy, an Ir-based compound, and a granular Ir layer with segregants. 19. The method of claim 18 , wherein the Ir-based alloy comprises one of an Iridium Titanium (IrTi) alloy, an Iridium Zirconium (IrZr) alloy, or an Iridium Carbon (IrC) alloy. 20. The method of claim 18 , wherein the segregants comprise at least one of light and heat absorbing materials.