Turbine blade attachment rails for attachment fillet stress reduction

What is claimed is: 1. A fir tree coupling comprising: a load beam having a longitudinal axis, a base, a first side, and a second side, a rail extending across the base of the load beam between the first side and the second side, at an angle, wherein the angle is at least one of acute or obtuse relative to the longitudinal axis of the load beam, and a tooth running parallel to the longitudinal axis and disposed on the first side of the load beam. 2. The fir tree coupling of claim 1 , wherein the rail comprises at least one of a convex sidewall having a convex curvature, a concave sidewall having a concave curvature, or a vertical sidewall extending perpendicular to the base. 3. The fir tree coupling of claim 1 , wherein the rail comprises a sidewall comprising a sidewall step wherein the sidewall has a step cut into a portion of the rail. 4. The fir tree coupling of claim 1 , wherein the rail comprises a tapered sidewall wherein the tapered sidewall extends at an angle to the base. 5. The fir tree coupling of claim 1 , wherein the tooth includes a bearing surface. 6. The fir tree coupling of claim 1 , wherein the load beam comprises a top surface and a cooling passage passing through the load beam from the base to the top surface. 7. The fir tree coupling of claim 6 , wherein the rail is proximate an opening of the cooling passage. 8. The fir tree coupling of claim 1 wherein, the load beam comprises at least one of nickel, nickel alloy, titanium, or titanium alloy. 9. The fir tree coupling of claim 1 , wherein the load beam comprises a monocrystalline material. 10. A blade assembly for a gas turbine engine comprising: a platform having a dorsal surface and a ventral surface, an airfoil extending from the dorsal surface, a fir tree coupling extending from the ventral surface, the fir tree coupling comprising a load beam having a longitudinal axis, a base, a first side, and a second side; a rail extending across the base of the load beam between the first side and the second side at an angle, wherein the angle is at least one of acute or obtuse relative to the longitudinal axis of the load beam; and a tooth running parallel to the longitudinal axis and disposed on the first side of the load beam. 11. The blade assembly of claim 10 , wherein the rail comprises at least one of a convex sidewall having a convex curvature, a concave sidewall having a concave curvature, or a vertical sidewall extending perpendicular to the base. 12. The blade assembly of claim 10 , wherein the rail comprises a sidewall comprising a sidewall step wherein the sidewall has a step cut into a portion of the rail. 13. The blade assembly of claim 10 , wherein the rail comprises a tapered sidewall wherein the tapered sidewall extends at an angle to the base. 14. The blade assembly of claim 10 , wherein at least one of the first cooling passages are in fluid communication with a second a cooling passage within at least one of the platform or the airfoil. 15. The blade assembly of claim 14 , further comprising additional rails wherein at least one of the additional rails is located outward of the cooling passages, along the longitudinal axis of the load beam. 16. The blade assembly of claim 10 wherein, the fir tree coupling comprises at least one of nickel, nickel alloy, titanium, or titanium alloy. 17. The blade assembly of claim 10 wherein, the fir tree coupling comprises a monocrystalline material. 18. A method of manufacturing a fir tree coupling comprising: forming a load beam having a longitudinal axis, a base, a first side, a second side, and a tooth running parallel to the longitudinal axis and disposed on the first side of the load beam; forming a rail extending at a an angle, wherein the angle is at least one of acute or obtuse relative to the longitudinal axis of the load beam, across the base of the load beam between the first side and the second side.