Flat panel x-ray imager with scintillating glass substrate

What is claimed is: 1. A structure comprising: a first scintillating screen that converts an absorbed portion of incident x-ray for medical radiography directed at the structure into light photons; a photosensor array; a second scintillating screen comprised of a scintillating glass, the photosensor array being between the first scintillating screen and the second scintillating screen, the scintillating glass converts an absorbed portion of the incident x-ray for medical radiography transmitted through the first scintillating screen and the photosensor array into light photons, where a surface of the first scintillating screen faces the photosensor array and a surface of the scintillating glass faces the photosensor array, wherein the surface of the scintillating glass is a substrate for the photosensor array without another substrate being between the scintillating glass and a 2D patterned metal layer, wherein the second scintillating screen further comprises a backing, the backing contacting another surface of the scintillating glass, the another surface being opposite of the surface facing the photosensor array, and the backing is absorptive to the light photons, wherein the photosensor array is operable to capture at least a portion of the light photons from the first scintillating screen and the second scintillating screen and convert the captured light photons into electrical signals, wherein the photosensor array comprises: a plurality of photosensitive storage elements for capturing the at least a portion of the light photons from the first scintillating screen and the second scintillating screen; a plurality of switching elements, where one switching element of the plurality of switching elements corresponds to one of the plurality of photosensitive storage elements, respectively; and a metal bias layer comprising transparent portions and non-transparent portions, and the 2D patterned metal layer comprising at least transparent portions, where each non-transparent portion of the metal bias layer aligns with a corresponding switching element as viewed from the metal bias layer to the 2D patterned metal layer and the non-transparent portions of the metal bias layer are configured to block light photons generated in the first scintillating screen from interacting with the corresponding switching element. 2. The structure of claim 1 , wherein the scintillating glass and the photosensor array are in direct optical contact with each other. 3. The structure of claim 1 , wherein the 2D patterned metal layer and the metal bias layer are comprised of indium tin oxide (ITO). 4. The structure of claim 1 , wherein the scintillating glass has a thickness about 200 microns to about 2000 microns, where the thickness is based on an application of the structure. 5. The structure of claim 1 , wherein the first scintillating screen comprises a scintillating phosphor layer. 6. The structure of claim 5 , wherein the scintillating phosphor layer is a powder or granular type, or a nanocrystalline powder type or perovskite scintillator type and the first scintillating screen further comprises a backing, the backing contacting the scintillating phosphor layer. 7. The structure of claim 6 , wherein the backing of the first scintillating screen is reflective or absorptive to the light photons based on an application of the structure. 8. The structure of claim 5 , wherein the scintillating phosphor layer is a structured or needle type. 9. The structure of claim 1 , wherein a thickness of the second scintillating screen is greater than a thickness of the first scintillating screen. 10. The structure of claim 1 , wherein the scintillating glass comprises luminescent nanocrystals in a glass matrix. 11. The structure of claim 1 , wherein the scintillating glass comprises rare-earth halides. 12. The structure of claim 1 , wherein the surface of the scintillating glass has a smoothness of less than about 20 nm RMS. 13. The structure of claim 1 , wherein the scintillating glass has a glass transition temperature above 300° C. 14. The structure of claim 1 , wherein the scintillating glass has a glass transition temperature above 600° C. 15. An imaging system comprising: a processor configured to be in communication with a structure comprising: a first scintillating screen that converts an absorbed portion of incident radiation directed at the structure into light photons; a photosensor array configured to produce an image having a plurality of pixels, each photosensor in the array comprises a photosensitive storage element and a switching element and represents a pixel in the image of the plurality of pixels, the photosensor array further comprising a metal bias layer comprising transparent portions and non-transparent portions and a 2D patterned metal layer comprising at least transparent portions, where each non-transparent portion of the metal bias layer aligns with a corresponding switching element as viewed from the metal bias layer to the 2D patterned metal layer and the non-transparent portions of the metal bias layer are configured to block light photons generated in the first scintillating screen from interacting with the corresponding switching element; and a second scintillating screen comprised of a scintillating glass, the photosensor array being between the first scintillating screen and the second scintillating screen, the scintillating glass converts an absorbed portion of the incident radiation transmitted through the first scintillating screen and the photosensor array into light photons, where a surface of the first scintillating screen faces the photosensor array and a surface of the scintillating glass faces the photosensor array, wherein the surface of the scintillating glass is a substrate for the photosensor array without another substrate being between the scintillating glass and the 2D patterned metal layer; wherein the photosensor array is operable to capture at least a portion of the light photons from the first scintillating screen and the second scintillating screen and convert the captured light photons into electrical signals, the processor is configured to: receive the electrical signals from the structure; and produce the image having the plurality of pixels using the electrical signals.