Disk lug cooling flow trenches

What is claimed is: 1. A rotor disk assembly, comprising: a rotor disk, comprising: a disk lug fixed to a distal surface of the rotor disk; and a trench disposed on a surface of the disk lug and extending radially inwards from a distal surface of the disk lug, wherein the trench is configured to at least partially define a flow path by which air may reach a distal surface of the disk lug; a retainer plate, wherein the flow path is partially defined by at least a portion of an aft surface of the retainer plate; a cover plate coupled to the rotor disk, wherein the flow path is partially defined by at least a portion of an aft surface of the cover plate; an aperture disposed in the cover plate, wherein the flow path is partially defined by the aperture; a blade platform coupled to the cover plate via the retainer plate; and a shield plate coupled between the distal surface of the disk lug and a proximal surface of the blade platform, wherein the flow path is partially defined by the distal surface of the disk lug and the proximal surface of the blade platform, wherein the retainer plate is coupled between the cover plate and the blade platform, a distal end of the retainer plate being mechanically retained from moving in a forward direction by the blade platform and a proximal end of the retainer plate being mechanically retained from moving in the forward direction by the cover plate. 2. The rotor disk assembly of claim 1 , wherein the trench is located on a forward side of the rotor disk. 3. The rotor disk assembly of claim 1 , wherein the disk lug is configured to couple the rotor disk to the blade platform. 4. The rotor disk assembly of claim 1 , wherein the rotor disk assembly is a high pressure turbine rotor disk assembly. 5. The rotor disk assembly of claim 1 , wherein the air is cooling air, wherein the flow path is configured to provide cooling to the disk lug. 6. The rotor disk assembly of claim 1 , wherein a length of the trench is less than a length of the disk lug. 7. The rotor disk assembly of claim 1 , wherein a width of the trench is less than a maximum width of the disk lug. 8. The rotor disk assembly of claim 1 , wherein the rotor disk comprises a nickel based alloy. 9. The rotor disk assembly of claim 1 , wherein the trench is manufactured via at least one of an additive process, a subtractive process, or an electrical discharge machining process. 10. A gas turbine engine, comprising: a rotor disk assembly, comprising: a blade platform; a cover plate; a retainer plate coupled between the blade platform and the cover plate; and a rotor disk, comprising: a disk lug fixed to a distal surface of the rotor disk; and a trench disposed on a surface of the disk lug and extending radially inwards from a distal surface of the disk lug, wherein the trench is configured to at least partially define a flow path by which air may reach a distal surface of the disk lug; wherein the flow path is partially defined by an aft surface of the retainer plate; the blade platform is coupled to the rotor disk via the disk lug; the cover plate is coupled to the rotor disk; and a distal end of the retainer plate is mechanically retained from moving in a forward direction by the blade platform and a proximal end of the retainer plate is mechanically retained from moving in the forward direction by the cover plate. 11. The gas turbine engine of claim 10 , wherein the trench is located on a forward side of the rotor disk.