Coated article and coating process therefor

What is claimed is: 1. A coating process comprising: preheating a workpiece having an aluminum-containing layer through a temperature range in a reducing atmosphere having hydrogen to thereby limit formation of thermally grown oxides on the surfaces of the workpiece; introducing a source of oxygen to establish an oxidizing atmosphere at a temperature above the temperature range to form a desired type of thermally grown oxide on the surfaces of the workpiece; and depositing a coating on the desired type of thermally grown oxide wherein the preheating is conducted at approximately ambient pressure. 2. A coating process as recited in claim 1 , wherein the most abundant element in the reducing atmosphere is the hydrogen. 3. The coating process as recited in claim 1 , wherein the introducing of the source of oxygen includes introducing moist hydrogen as the source of oxygen. 4. The coating process as recited in claim 3 , wherein the introducing of the moist hydrogen includes flowing hydrogen gas through liquid water to provide the moist hydrogen. 5. The coating process as recited in claim 1 , wherein the temperature range is 700° F.-1800° F. (371° C.-982° C.) and the temperature at which the source of oxygen is introduced is 1850° F.-1950° F. (1010° C.-1065° C.). 6. The coating process as recited in claim 1 , wherein the depositing of the coating includes depositing a coating selected from a group consisting of zirconia, hafnia, and combinations thereof. 7. The coating process as recited in claim 1 , wherein the workpiece is a metallic workpiece and the desired type of thermally grown oxide is alpha alumina. 8. The coating process as recited in claim 1 , wherein the preheating includes preheating in the reducing atmosphere at a first pressure and then, above the temperature range, reducing the first pressure to a second pressure for introducing the source of oxygen. 9. The coating process as recited in claim 1 , wherein the hydrogen in the preheating consumes oxygen present in the reducing atmosphere to prevent the oxygen from reacting with the aluminum-containing layer. 10. The coating process as recited in claim 1 , wherein the preheating includes repeatedly back-filling with the hydrogen, pumping down, and back-filling with the hydrogen again to purge other gases such that the hydrogen is the most abundant element in the reducing atmosphere on a molar basis. 11. The coating process as recited in claim 1 , wherein, in the preheating, there is there is not enough oxygen to overcome the hydrogen and oxidize the aluminum-containing layer to form the thermally grown oxides on the surfaces of the workpiece and, after the introduction of the source of oxygen, there is enough oxygen to overcome the hydrogen and oxidize the aluminum-containing layer to form the desired type of thermally grown oxide on the surfaces of the workpiece. 12. The coating process as recited in claim 1 , wherein the reducing atmosphere stops formation of thermally grown oxides on the surfaces of the workpiece. 13. A coating process comprising: preheating a workpiece having an aluminum-containing layer through a temperature range in a reducing atmosphere having hydrogen to thereby limit formation of thermally grown oxides on the surfaces of the workpiece; introducing a source of oxygen to establish an oxidizing atmosphere at a temperature above the temperature range to form a desired type of thermally grown oxide on the surfaces of the workpiece; and depositing a coating on the desired type of thermally grown oxide wherein the source of oxygen is carbon dioxide. 14. The coating process as recited in claim 13 , wherein the preheating is conducted at a sub-ambient pressure. 15. A coating process comprising: preheating a workpiece having an aluminum-containing layer through a temperature range in a reducing atmosphere having hydrogen to thereby limit formation of thermally grown oxides on the surfaces of the workpiece; introducing a source of oxygen to establish an oxidizing atmosphere at a temperature above the temperature range to form a desired type of thermally grown oxide on the surfaces of the workpiece; and depositing a coating on the desired type of thermally grown oxide wherein the source of oxygen is a mixture of carbon dioxide and hydrogen. 16. The coating process as recited in claim 15 , wherein the preheating is conducted at a sub-ambient pressure. 17. A coating process comprising: preheating a workpiece having an aluminum-containing layer through a temperature range in a reducing atmosphere having hydrogen to thereby limit formation of thermally grown oxides on the surfaces of the workpiece; introducing a source of oxygen to establish an oxidizing atmosphere at a temperature above the temperature range to form a desired type of thermally grown oxide on the surfaces of the workpiece; and depositing a coating on the desired type of thermally grown oxide, wherein the hydrogen in the preheating consumes oxygen present in the reducing atmosphere to prevent the oxygen from reacting with the aluminum-containing layer. 18. The coating process as recited in claim 17 , wherein: the temperature range is 700° F.-1800° F. (371° C.-982° C.) and the temperature at which the source of oxygen is introduced is 1850° F.-1950° F. (1010° C.-1065° C.), the depositing of the coating includes depositing a coating selected from the group consisting of zirconia, hafnia, and combinations thereof, and the workpiece is a metallic workpiece and the desired type of thermally grown oxide is alpha alumina. 19. The coating process as recited in claim 17 , wherein the preheating includes preheating in the reducing atmosphere at a first pressure and then, above the temperature range, reducing the first pressure to a second pressure for introducing the source of oxygen. 20. The coating process as recited in claim 17 , wherein, in the preheating, there is there is not enough oxygen to overcome the hydrogen and oxidize the aluminum-containing layer to form the thermally grown oxides on the surfaces of the workpiece and, after the introduction of the source of oxygen, there is enough oxygen to overcome the hydrogen and oxidize the aluminum-containing layer to form the desired type of thermally grown oxide on the surfaces of the workpiece.