Methods of manufacturing glass articles using anisothermal temperature profiles

The invention claimed is: 1. A method of manufacturing a glass article having a three-dimensional shape comprising: heating a glass article blank to a temperature above a setting temperature; controlling a first portion of a molding region of an open-faced mold to have a first temperature and a second portion of the molding region of the open-faced mold to have a second temperature effective to generate an anisothermal temperature profile within the molding region, the molding region having a three-dimensional shape that generally corresponds to the three-dimensional shape of the glass article, wherein the first and second temperatures are above an ambient temperature and below the setting temperature; coupling the heated glass article blank to a contact face of the open-faced mold including the anisothermal temperature profile; maintaining an anisothermal temperature profile along the glass article blank; cooling a portion of the open-faced mold proximate to the molding region by directing a fluid cooling stream through a cooling passage in the open-faced mold, wherein the cooling passage comprises a portion that is positioned proximate to the molding region and is fluidly isolated from the contact face of the open-faced mold; adjusting a flow rate of the fluid cooling stream through the cooling passage to control the anisothermal temperature profile along the glass article blank; and cooling the glass article blank while coupled to the molding region of the open-faced mold to set the three-dimensional shape of the glass article, wherein when the glass article blank is being cooled, a thermal gradient is maintained through a thickness of the glass article blank thereby causing a pre-determined warp of the glass article blank that contributes to the three-dimensional shape of the glass article. 2. The method of claim 1 , further comprising decoupling the glass article from the open-faced mold when a maximum temperature of the glass article is within a viscoelastic temperature range of the glass article for a given cooling rate. 3. The method of claim 1 , further comprising heating the glass article blank along a side opposite a side of the glass article blank that contacts the open-faced mold. 4. The method of claim 1 , wherein a shape of the glass article differs from the shape of the molding region of the open-faced mold. 5. The method of claim 1 , further comprising forming an ion exchanged surface layer having a depth of layer into the glass article. 6. The method of claim 5 , wherein forming the ion exchanged surface layer modifies the shape of the glass article so that the glass article has a shape that differs from the shape of the molding region of the open-faced mold. 7. The method of claim 1 , wherein the molding region comprises a high contoured portion and a low contoured portion, and the glass article comprises a high stress field at positions proximate to the high contoured portion of the molding region and a low stress field at positions proximate to the low contoured portion of the molding region. 8. A method of manufacturing a glass article having a three-dimensional shape comprising: heating a glass article blank to a temperature above a setting temperature; controlling a first portion of an open-faced mold to have a first temperature and a second portion of the open-face mold to have a second temperature effective to generate an anisothermal temperature profile for the open-faced mold, the open-faced mold having a three-dimensional shape that differs from a target shape for the glass article, wherein the first and second temperatures are above an ambient temperature and below the setting temperature; coupling the heated glass article blank to a contact face of the open-faced mold having the anisothermal temperature profile; maintaining an anisothermal temperature profile along the glass article blank; cooling a portion of the open-faced mold proximate to the molding region by directing a fluid cooling stream through a cooling passage in the open-faced mold, wherein the cooling passage comprises a portion that is positioned proximate to the molding region and is fluidly isolated from the contact face of the open-faced mold; adjusting a flow rate of the fluid cooling stream through the cooling passages to control the anisothermal temperature profile along the glass article blank; cooling the glass article blank to a temperature below a viscous temperature while coupled to the open-faced mold to set the three-dimensional shape of the glass article, wherein when the glass article blank is being cooled, a thermal gradient is maintained through a thickness of the glass article blank thereby causing a pre-determined warp of the glass article blank that contributes to the target shape of the glass article; and releasing the glass article from the open-faced mold. 9. The method of claim 8 , wherein cooling the glass article blank is performed at a first flow rate, the method further comprising: determining that the three-dimensional shape of the glass article differs from the target shape for the glass article; and selecting a second flow rate, the second cooling rate differing from the first cooling rate, wherein the second flow rate generates an alternate anisothermal temperature profile for the open-faced mold; and cooling a subsequent glass article blank according to the second flow rate to the setting temperature while coupled to the open-faced mold to set a three-dimensional shape of a subsequent glass article. 10. The method of claim 8 , wherein the three-dimensional shape of the glass article generally corresponds to the target shape for the glass article. 11. The method of claim 8 , wherein heating the glass article blank to the temperature above the setting temperature comprises heating the glass article blank to a temperature at which greater than about 75% of the stresses of the glass article blank are relaxed for a given cooling rate. 12. The method of claim 8 , wherein cooling the glass article blank to the setting temperature while coupled to the open-faced mold comprises cooling the glass article blank to a temperature at which less than approximately 20% of the stresses of the glass are relaxed for a given cooling rate.