Vacuum photosensor device with electron lensing

What is claimed is: 1. A photosensor apparatus, comprising: a first housing of an optically transparent dielectric material window having a conductive layer as a photocathode for converting photons into photoelectrons; a base plate to which said first housing is attached; a through-channel centrally located on said base plate; a windowlet, within or covering said through-channel, configured for directing light from said first housing through said through-channel of said base plate; a scintillator surface on said windowlet for converting electron impacts upon said scintillator surface into secondary light transmitted through said windowlet; a first electrically conductive hermetic seal between a periphery of said first housing in electrical contact with said photocathode, and a periphery of said base plate; a second electrically conductive hermetic seal, between said windowlet and said through-channel with said base plate, which is in electrical contact with said scintillator; wherein said first housing is configured with said first and second electrically conductive hermetic seals for retaining an ultrahigh vacuum level between said optically transparent dielectric material window and said base plate; a second housing disposed on a back side of said base plate having an interior shape for focusing photoelectrons converted at said photocathode layer of said optically transparent dielectric material window upon said windowlet in response to a high voltage applied between said first and second electrically conductive hermetic seals to which electrical connections are established within said second housing; wherein said second housing is not subject to said ultrahigh vacuum level of said first housing; an optical detector retained within said second housing and having a sensing area positioned in said second housing for receiving secondary light from said windowlet; and wherein an electrostatic field formed by said first housing, said second housing and said second electrically conductive hermetic seal focuses photoelectrons from said photocathode onto said scintillator surface, which has a surface area multiple orders of magnitude smaller than that of said photocathode. 2. An apparatus as recited claim 1 , wherein said first housing has a concave shape. 3. An apparatus as recited claim 2 , wherein said second housing has a concave shape and is configured with a conductive layer as a cathode. 4. An apparatus as recited claim 3 : wherein said first and second housing have a hemispherical shape; wherein an electron lens is created in response to a nearly spherically shaped electrostatic potential formed between said photocathode in said first housing and said second housing acting as a cathode, and said second electrically conductive hermetic seal with said through-channel as the anode; and wherein said electron lens focuses and accelerates electrons from this nearly spherically shaped photocathode surface to the scintillator disposed upon said through-channel. 5. An apparatus as recited claim 1 , wherein said second electrically conductive hermetic seal is reflective for retaining secondary light passing through said windowlet from being dispersed in said base plate. 6. An apparatus as recited claim 1 , wherein said optical detector retained within said second housing is selected from the group of sensors consisting of semiconductor detectors, avalanche photo diodes, and Geiger-mode avalanche photo diodes. 7. An apparatus as recited claim 1 , further comprising a high-voltage insulating material filling empty space within said second housing. 8. An apparatus as recited claim 1 , further comprising a set of concentric electrically conductive, residual gas absorbing, and light-reflective thin film rings on said base plate acting as floating electrodes. 9. An apparatus as recited claim 1 , wherein said optically transparent dielectric material of said first housing, said base plate, and said windowlet are shaped with an open geometry suitable for being removed from a mold. 10. An apparatus as recited claim 1 , wherein said through-channel and said windowlet have an active area which is at least two orders of magnitude less than that of said photocathode. 11. An apparatus as recited claim 1 , further comprising a high voltage source disposed within said second housing coupled to said first and second electrically conductive hermetic seal. 12. An apparatus as recited claim 1 , wherein said first housing, said base plate, and said windowlet comprise materials selected from the group of dielectric materials consisting of transparent dielectric materials, glass, quartz, and fused silica. 13. An apparatus as recited claim 1 , wherein said windowlet comprises a scintillator crystal material. 14. An apparatus as recited claim 1 , wherein said scintillator surface comprises a thin film of electrically conductive and optically reflective material disposed over said windowlet. 15. An apparatus as recited claim 1 , wherein said windowlet covering said through-channel has a diameter at least five times smaller than the outer diameter of said base plate. 16. An apparatus as recited claim 1 , wherein said first and second electrically conductive hermetic seal comprises metallic layers deposited in an ultrahigh vacuum on a surface of each element to be joined. 17. An apparatus as recited claim 16 , wherein after assembling each element to be joined, said electrically conductive hermetic seal is activated to seal joined elements. 18. An apparatus as recited claim 16 , wherein said electrically conductive hermetic seal is electrically conductive, free of oxides and liquid above a temperature above approximately 160° C. 19. An apparatus as recited claim 16 , wherein said electrically conductive hermetic seal comprises layers of chromium, gold and indium. 20. A photosensor apparatus, comprising: a concave hemispherical window of optically transparent dielectric material having a photocathode layer on its concave surface and with a flat ending annulus on a concave side in or near the plane passing through the center of curvature; a base plate comprising dielectric material which is hermetically sealed to said concave hemispherical window to retain an ultrahigh vacuum therebetween; a through-channel centrally located within said base plate; a windowlet disposed within or over said through-channel; a scintillator surface disposed on said windowlet for converting electron impacts upon said scintillator surface into secondary light transmitted through said windowlet and said through-channel; a first electrically conductive hermetic seal between said flat ending annulus of said concave hemispherical window and a periphery of said base plate; a second electrically conductive hermetic seal between through-channel and said windowlet and said base plate; wherein said photocathode layer converts photons striking said photosensor into photoelectrons and concentrates these photoelectrons from said photocathode upon said optical detector; wherein as surface area of said photocathode is multiple orders of magnitude larger than a sensing area of said optical detector, the photoelectron activity striking said apparatus is concentrated by many orders of magnitude; and at least one optical detector disposed in optical communication with said through-channel and said windowlet outside of said ultrahigh vacuum between said base plate and said concave hemispherical window, and configured for generating an electrical signal in response to regis