Methods for fabricating radiation-detecting structures are presented. The methods include, for instance: fabricating a radiation-detecting structure, the fabricating including: providing a semiconductor substrate, the semiconductor substrate having a plurality of cavities extending into the semiconductor substrate from a surface thereof; and electrophoretically depositing radiation-detecting particles of a radiation-detecting material into the plurality of cavities extending into the semiconductor substrate, where the electrophoretically depositing fills the plurality of cavities with the radiation-detecting particles. In one embodiment, the providing can include electrochemically etching the semiconductor substrate to form the plurality of cavities extending into the semiconductor substrate. In addition, the providing can further include patterning the surface of the semiconductor substrate with a plurality of surface defect areas, and the electrochemically etching can include using the plurality of surface defect areas to facilitate electrochemically etching into the semiconductor substrate through the plurality of surface defect areas to form the plurality of cavities.

The present invention is a photodiode or photodiode array having improved ruggedness for a shallow junction photodiode which is typically used in the detection of short wavelengths of light. In one embodiment, the photodiode has a relatively deep, lightly-doped P zone underneath a P+ layer. By moving the shallow junction to a deeper junction in a range of 2-5 m below the photodiode surface, the improved device has improved ruggedness, is less prone to degradation, and has an improved linear current.

Methods for fabricating radiation-detecting structures are presented. The methods include, for instance: fabricating a radiation-detecting structure, the fabricating including: providing a semiconductor substrate, the semiconductor substrate having a plurality of cavities extending into the semiconductor substrate from a surface thereof; and electrophoretically depositing radiation-detecting particles of a radiation-detecting material into the plurality of cavities extending into the semiconductor substrate, where the electrophoretically depositing fills the plurality of cavities with the radiation-detecting particles. In one embodiment, the providing can include electrochemically etching the semiconductor substrate to form the plurality of cavities extending into the semiconductor substrate. In addition, the providing can further include patterning the surface of the semiconductor substrate with a plurality of surface defect areas, and the electrochemically etching can include using the plurality of surface defect areas to facilitate electrochemically etching into the semiconductor substrate through the plurality of surface defect areas to form the plurality of cavities.

An semiconductor detector includes an n-type semiconductor substrate, a detection electrode formed on a first surface of the semiconductor substrate, a plurality of drift electrodes formed to surround the detection electrode and applied with a voltage causing a potential gradient in which a potential changes toward the detection electrode, a radiation incidence window provided on a second surface of the semiconductor substrate, a P-type semiconductor region formed by adding boron to a surface side on the second surface of the semiconductor substrate through the radiation incidence window, and a depleting electrode causing a reverse bias between the P-type semiconductor region formed on the second surface and an N-type semiconductor region formed in the semiconductor substrate. F is added to the P-type semiconductor region, and a region with the highest concentration of F is located deeper than a region with the highest concentration of B.

An isotope capacitor may include a plurality of isotope capacitor sheets that are stacked in a first direction, a first external electrode, and a second external electrode. Each isotope capacitor sheet of the plurality of isotope capacitor sheets includes a substrate including a first material and a second material and a radiation source. The second material may have an electrical conductivity higher than the electrical conductivity of the first material. The second material may be between the first material and the radiation source. The first external electrode and the second external electrode may be configured to transfer electrical energy generated by the plurality of stacked capacitor sheets to an external load.