The present embodiment relates to a radiation detector having a structure enabling suppression of polarization in a thallium bromide crystalline body and suppression of corrosion of an electrode in the air. The radiation detector comprises a first electrode, a second electrode, and a thallium bromide crystalline body provided between the first and second electrodes. At least one of the first electrode and the second electrode includes an alloy layer 12. The alloy layer is comprised of an alloy of metallic thallium and another metal different from the metallic thallium.

A charged particle detector is provided. The charged particle detector includes a flexible semiconductor wafer, the semiconductor wafer being doped to form a p-n junction, and an amplifier coupled to the semiconductor wafer and configured to amplify a current or voltage across the p-n junction.

Various methods and systems are provided for three layer photolithography. In one embodiment, a process includes disposing a radiation hard dielectric layer on a substrate, the radiation hard dielectric layer comprising a dielectric that maintains defined dielectric properties when exposed to at least 50 mrads of proton radiation and/or at least 410.sup.15 of 1 MeV equivalent neutron radiation; patterning the radiation hard dielectric layer; and treating the radiation hard dielectric layer. In one embodiment, a device includes a substrate and a patterned radiation hard dielectric layer disposed on the substrate, the radiation hard dielectric layer comprising a dielectric that maintains defined dielectric properties when exposed to at least 50 mrads of proton radiation and/or at least 410.sup.15 of 1 MeV equivalent neutron radiation.

Various methods and systems are provided for three layer photolithography. In one embodiment, a process includes disposing a radiation hard dielectric layer on a substrate, the radiation hard dielectric layer comprising a dielectric that maintains defined dielectric properties when exposed to at least 50 mrads of proton radiation and/or at least 410.sup.15 of 1 MeV equivalent neutron radiation; patterning the radiation hard dielectric layer; and treating the radiation hard dielectric layer. In one embodiment, a device includes a substrate and a patterned radiation hard dielectric layer disposed on the substrate, the radiation hard dielectric layer comprising a dielectric that maintains defined dielectric properties when exposed to at least 50 mrads of proton radiation and/or at least 410.sup.15 of 1 MeV equivalent neutron radiation.

The photodiode device comprises a substrate (1) of semiconductor material with a main surface (10), a plurality of doped wells (3) of a first type of conductivity, which are spaced apart at the main surface (10), and a guard ring (7) comprising a doped region of a second type of conductivity, which is opposite to the first type of conductivity. The guard ring (7) surrounds an area of the main surface (10) including the plurality of doped wells (3) without dividing this area. Conductor tracks (4) are electrically connected with the doped wells (3), which are thus interconnected, and further conductor tracks (5) are electrically connected with a region of the second type of conductivity. A doped surface region (2) of the second type of conductivity is present at the main surface (10) and covers the entire area between the guard ring (7) and the doped wells (3).

The photodiode device comprises a substrate (1) of semiconductor material with a main surface (10), a plurality of doped wells (3) of a first type of conductivity, which are spaced apart at the main surface (10), and a guard ring (7) comprising a doped region of a second type of conductivity, which is opposite to the first type of conductivity. The guard ring (7) surrounds an area of the main surface (10) including the plurality of doped wells (3) without dividing this area. Conductor tracks (4) are electrically connected with the doped wells (3), which are thus interconnected, and further conductor tracks (5) are electrically connected with a region of the second type of conductivity. A doped surface region (2) of the second type of conductivity is present at the main surface (10) and covers the entire area between the guard ring (7) and the doped wells (3).

There is provided a semiconductor detector. According to an embodiment, the semiconductor detector may include a semiconductor detection material including a first side and a second side opposite to each other. One of the first side and the second side is a ray incident side that receives incident rays. The detector may further include a plurality of pixel cathodes disposed on the first side and a plurality of pixel anodes disposed on the second side. The pixel anodes and the pixel cathodes correspond to each other one by one. The detector may further include a barrier electrode disposed on a periphery of respective one of the pixel cathodes or pixel anodes on the ray incident side. According to the embodiment of the present disclosure, it is possible to effectively suppress charge sharing between the pixels and thus to improve an imaging resolution of the detector.

There is provided a semiconductor detector. According to an embodiment, the semiconductor detector may include a semiconductor detection material including a first side and a second side opposite to each other. One of the first side and the second side is a ray incident side that receives incident rays. The detector may further include a plurality of pixel cathodes disposed on the first side and a plurality of pixel anodes disposed on the second side. The pixel anodes and the pixel cathodes correspond to each other one by one. The detector may further include a barrier electrode disposed on a periphery of respective one of the pixel cathodes or pixel anodes on the ray incident side. According to the embodiment of the present disclosure, it is possible to effectively suppress charge sharing between the pixels and thus to improve an imaging resolution of the detector.

Provided herein is a diamond gammavoltaic cell comprising: a diamond body having a diamond body surface including first and second opposing surfaces; a low-barrier electrical contact formed on the first surface; and a high-barrier electrical contact formed on the second surface, wherein the diamond body surface that is not in contact with either the low-barrier electrical contact or the high-barrier electrical contact is at least partially surface transfer doped to provide a p-type surface.

Provided herein is a diamond gammavoltaic cell comprising: a diamond body having a diamond body surface including first and second opposing surfaces; a low-barrier electrical contact formed on the first surface; and a high-barrier electrical contact formed on the second surface, wherein the diamond body surface that is not in contact with either the low-barrier electrical contact or the high-barrier electrical contact is at least partially surface transfer doped to provide a p-type surface.