Semiconductor scintillation detector

The invention claimed is: 1. A radiation detection device for detecting gamma or x-ray radiation quanta comprising: a semiconductor scintillator element having two mutually opposing faces; at least one photodetector that is in optical communication with the scintillator element; wherein the at least one photodetector has a photodetector electrical output that is configured to generate a first electrical signal at the photodetector electrical output that is indicative of the time of reception of a detected gamma or x-ray radiation quantum; at least one cathode in electrical communication with at least a portion of one of the two scintillator element faces; at least one anode in electrical communication with at least a portion of the other of the two scintillator element faces; wherein at least one of the at least one cathode or the at least one anode is configured to generate a second electrical signal that is indicative of the energy of the detected gamma or x-ray radiation quantum. 2. The radiation detection device according to claim 1 wherein the second electrical signal is generated subsequently to the first electrical signal. 3. The radiation detection device according to claim 1 wherein the semiconductor scintillator element has an amorphous structure or a polycrystalline structure or a ceramic structure. 4. The radiation detection device according to claim 3 further comprising a shielding electrode; wherein the shielding electrode is a conductive planar layer embedded within the scintillator element between the anode and the cathode and electrically isolated from the scintillator element; and wherein the electrically-isolated conductive layer has a plurality of perforations that are configured to permit the passage of electrons along a path from the region between the conductive layer and the cathode to the region between the conductive layer and the anode. 5. The radiation detecting device according to claim 3 , wherein the semiconductor scintillator element is formed at an elevated temperature and further including: an electrode embedded within the scintillator element, the electrode being constructed of a refractory metal with a melting point that exceeds a melting temperature of the semiconductor scintillator element and being coated with an oxide insulator with a melting point higher than the melting point of the semiconductor scintillator element. 6. The radiation detection device according to claim 1 in which the at least one anode is a plurality of laterally-separated anodes. 7. The radiation detection device according to claim 6 further comprising a common steering electrode disposed on the same scintillator element face as the plurality of anodes; wherein the common steering electrode includes a plurality of electrically inter-connected conductive regions that are disposed between or around the anodes such that adjacent anodes are laterally separated by at least a portion of the common steering electrode. 8. The radiation detection device according to claim 1 having a single anode and further comprising a common steering electrode disposed on the same scintillator element face as the anode; wherein the common steering electrode surrounds the anode such that there is a gap between the anode and the common steering electrode. 9. The radiation detection device according to claim 1 in which the at least one anode is a plurality of laterally-separated anodes and in which the at least one cathode is a plurality of laterally-separated cathodes; wherein the anodes are formed from a plurality of conductive strips extending in a first direction and the cathodes are formed from a plurality of conductive strips extending in a second direction; wherein the first direction and the second direction are mutually transverse. 10. The radiation detection device according to claim 1 wherein the semiconductor scintillator element includes a plurality of side faces disposed between the two mutually opposing faces, and further including: a shielding electrode having a conductive ring that is disposed around the side faces of the scintillator element and dielectrically isolated from the side faces of the semiconductor scintillator element, wherein the conductive ring is biased to allow electrons to pass the anode and inhibiting holes from passing to the anode. 11. The radiation detection device according to claim 1 in which the at least one anode is a plurality of laterally-separated anodes; the device further comprising: electronic circuitry configured for each anode to convert electrical charge collected at that anode into an electrical current or voltage signal; electronic circuitry or a processor configured to receive the electrical current or voltage signals and to compute the lateral position of interaction of a radiation quantum received by the scintillator element based on the relative magnitudes of the electrical current or voltage signals. 12. The radiation detection device according to claim 1 further comprising: electronic circuitry configured for each anode to convert electrical charge collected at that anode into an electrical current or voltage signal; electronic circuitry or a processor configured to receive the one or more electrical current or voltage signals and to compute the energy of a gamma or x-ray radiation quantum received by the scintillator element by summing the magnitudes of the one or more electrical current or voltage signals to generate a summed signal indicative of the total charge collected at the one or more anodes. 13. The radiation detection device according to claim 1 further comprising: first timing circuitry configured to receive electrical signals generated by each of the at least one photodetector in response to the reception of a gamma or x-ray radiation quantum and to generate a first timestamp indicative of the earliest time at which an electrical signal generated by any of the at least one photodetector exceeds a first predetermined threshold; electronic circuitry configured for each anode to convert electrical charge collected at that anode into an electrical current or voltage signal; second timing circuitry configured to receive the electrical current or voltage signals generated from electrical charge collected by each anode in response to the reception of the gamma or x-ray radiation quantum and to generate a second timestamp indicative of the time at which at least one of the electrical current or voltage signals exceed a second predetermined threshold; electronic circuitry or a processor configured to compute a depth of interaction of the radiation quantum in the scintillator element based on the time difference between the first timestamp and the second timestamp. 14. A PET or x-ray imaging system comprising the radiation detection device of claim 1 . 15. The radiation detector device according to claim 1 , further including: an electrode embedded in the semiconductor scintillator element between the anode and the cathode, the electrode including: one or more electrical conductors which define a plurality of perforations; and an electrically insulating coating configured to electrically isolate the one or more electrical conductors from the semiconductor scintillator element, wherein the perforations defined by the one or more electrical conductors coated by the electrically insulating coating are configured to pass electrons therethrough. 16. A radiation detection device for detecting gamma or x-ray radiation quanta comprising: a semiconductor scintillator element having two mutually opposing faces, a firs