Casting core removal through thermal cycling

What is claimed is: 1. A method of removing a core of a cast component, comprising: providing a casting in a temperature controlled closed volume, the casting surrounding a silica based ceramic core; cycling temperature between a first temperature and a second temperature within the temperature controlled closed volume that repeatedly subjects the silica based ceramic core to a beta-to-alpha cristobalite transition that induces microfractures in the silica based ceramic core; and after the cycling temperature, in a volume different than the temperature controlled closed volume, chemically dissolving the silica based ceramic core from the casting. 2. The method of claim 1 where the temperature controlled closed volume comprises at least one of an autoclave, a gas fired kiln, or a resistively heated furnace box. 3. The method of claim 1 where the temperature controlled closed volume comprises a temperature controlled closed pressure volume. 4. The method of claim 1 , where the first temperature is 175 degrees C. and the second temperature is 300 degrees C. 5. The method of claim 1 , where the first temperature is less than 200 degrees C. and the second temperature is at least 275 degrees C. 6. The method of claim 1 , wherein the cycling comprises repeatedly increasing the temperature within the temperature controlled closed volume from the first temperature to the second temperature and lowering the temperature within the temperature controlled closed volume from the second temperature to the first temperature. 7. A method of removing a core of an airfoil cast component, comprising: inserting the airfoil cast component, which includes a silica based ceramic core embedded within the airfoil cast component, into a temperature controlled vessel; cycling temperature, within the temperature controlled vessel, between a first temperature and a second temperature a plurality of times that repeatedly subjects the silica based ceramic core to at least one phase transition that induces microfractures in the silica based ceramic core; and after the cycling temperature, in a vessel different than the temperature controlled vessel, chemically dissolving the silica based ceramic core from the airfoil cast component. 8. The method of claim 7 , where the temperature controlled vessel comprises an autoclave. 9. The method of claim 7 , where the first temperature is less than 200 degrees C. and the second temperature is at least 275 degrees C. 10. The method of claim 9 , where the plurality of times is at least five. 11. The method of claim 10 , where repeatedly cycling between the second temperature, where the core is transitioned to beta cristobalite phase, and the first temperature, where the core is transitioned to alpha cristobalite phase, repeatedly subjects the core to beta-to-alpha transitions that induce the microfractures in the core. 12. The method of claim 9 , where the plurality of times is at least ten. 13. The method of claim 7 , wherein the cycling comprises repeatedly raising the temperature within the temperature controlled vessel from the first temperature to the second temperature and then lowering the temperature within the temperature controlled vessel from the second temperature to the first temperature. 14. The method of claim 7 , wherein the cycling comprises raising the temperature within the temperature controlled vessel from the first temperature to the second temperature and then lowering the temperature within the temperature controlled vessel from the second temperature to the first temperature; and again raising the temperature within the temperature controlled vessel from the first temperature to the second temperature and then lowering the temperature within the temperature controlled vessel from the second temperature to the first temperature. 15. A method of removing a silica-based ceramic core, the method comprising: disposing a casting within a vessel, wherein the silica-based ceramic core is within and surrounded by the casting; increasing a temperature within the vessel from a first temperature to a second temperature to increase a temperature of the silica-based ceramic core for a first heating iteration; decreasing the temperature within the vessel from the second temperature to the first temperature to decrease the temperature of the silica-based ceramic core for a first cooling iteration; increasing the temperature within the vessel from the first temperature to the second temperature to increase the temperature of the silica-based ceramic core for a second heating iteration; decreasing the temperature within the vessel from the second temperature to the first temperature to decrease the temperature of the silica-based ceramic core for a second cooling iteration; and after the second cooling iteration, chemically dissolving the silica based ceramic core from within the casting.