The present disclosure relates to a semiconductor photomultiplier comprising a substrate; an array of photosensitive cells formed on the substrate that are operably coupled between an anode and a cathode. A set of primary bus lines are provided each being associated with a corresponding set of photosensitive cells. A secondary bus line is coupled to the set of primary bus lines. An electrical conductor is provided having a plurality of connection sites coupled to respective connection locations on the secondary bus line for providing conduction paths which have lower impedance than the secondary bus line.

After sequentially forming a first multilayer structure comprising a first set of semiconductor layers suitable for formation of a photodetector, an etch stop layer and a second multilayer structure comprising a second set of semiconductor layers suitable for formation of a light source over a substrate, the second multilayer structure is patterned to form a light source in a first region of the substrate. A first trench is then formed extending through the etch stop layer and the first multilayer structure to separate the first multilayer structure into a first part located underneath the light source and a second part that defines a photodetector located in a second region of the substrate. Next, an interlevel dielectric (ILD) layer is formed over the light source, the photodetector and the substrate. A second trench that defines a microfluidic channel is formed within the ILD layer and above the photodetector.

A structure includes a silicon substrate; silicon readout circuitry disposed on a first portion of a top surface of the substrate and a radiation detecting pixel disposed on a second portion of the top surface of the substrate. The pixel has a plurality of radiation detectors connected with the readout circuitry. The plurality of radiation detectors are composed of at least one visible wavelength radiation detector containing germanium and at least one infrared wavelength radiation detector containing a Group III-V semiconductor material. A method includes providing a silicon substrate; forming silicon readout circuitry on a first portion of a top surface of the substrate and forming a radiation detecting pixel, on a second portion of the top surface of the substrate, that has a plurality of radiation detectors formed to contain a visible wavelength detector composed of germanium and an infrared wavelength detector composed of a Group III-V semiconductor material.

A split electrode vertical cavity optical device includes an n-type ohmic contact layer, first through fifth ion implant regions, cathode and anode electrodes, first and second injector terminals, and p and n type modulation doped quantum well structures. The cathode electrode and the first and second ion implant regions are formed on the n-type ohmic contact layer. The third ion implant region is formed on the first ion implant region and contacts the p-type modulation doped QW structure. The fourth ion implant region encompasses the n-type modulation doped QW structure. The first and second injector terminals are formed on the third and fourth ion implant regions, respectively. The fifth ion implant region is formed above the n-type modulation doped QW structure and the anode electrode is formed above the fifth ion implant region.

A semiconductor device includes an n-type ohmic contact layer, cathode and anode electrodes, p-type and n-type modulation doped quantum well (QW) structures, and first and second ion implant regions. The anode electrode is formed on the first ion implant region that contacts the p-type modulation doped QW structure and the cathode electrode is formed by patterning the first and second ion implant regions and the n-type ohmic contact layer. The semiconductor device is configured to operate as at least one of a diode laser and a diode detector. As the diode laser, the semiconductor device emits photons. As the diode detector, the semiconductor device receives an input optical light and generates a photocurrent.

A radiation sensor includes a fin structure including semiconductor material formed on a substrate, a gate formed on an inner side of the fin structure, and a charge collector dielectric layer formed on an outer side of the fin structure.

A semiconductor device is provided. The device generates a signal based on both a first carrier generated in a first photodiode and a second carrier generated in a second photodiode. The first photodiode includes a first region of a second conductivity type and a second region of a first conductivity type arranged between a surface of a substrate and the first region. The second photodiode includes a third region of the first conductivity type and a fourth region of the second conductivity type arranged between the surface and the third region. A fifth region of the first conductivity type is provided at a position farther apart from the surface than the first region. A peak of an impurity concentration of the third region is positioned in a range where the first region exists between the second region and the fifth region.

In a photoelectric changing unit, a photoelectric conversion unit converts light into electric charge, and an electric charge accumulation unit accumulates the electric charge in a polygonal area whose plurality of sides are adjacent to the photoelectric conversion unit on a light receiving surface. A voltage generation unit accumulates the electric charge and generates a voltage according to an amount of the accumulated electric charge. A first transfer unit transfers the electric charge from the photoelectric conversion unit to the electric charge accumulation unit when an instruction on a transfer to the electric charge accumulation unit is issued. A second transfer unit transfers the electric charge from the electric charge accumulation unit to the voltage generation unit when an instruction on a transfer to the voltage generation unit is issued.

To provide a solid-state light-receiving device for ultraviolet light which can measure the amount of irradiation with ultraviolet light harmful to the human body using a simplified structure and properly and accurately, which can be readily integrated with a sensor of a peripheral circuit, which is small, light-weight, and low-cost, and which is suitable for mobile or wearable purposes. One solution is a solid-state light-receiving device for ultraviolet light which is provided with a first photodiode (1), a second photodiode (2), and a differential circuit which receives respective signals based on outputs from these photodiodes, wherein a position of the maximum concentration of a semiconductor impurity is provided in each of the photodiodes (1,2) and in a semiconductor layer region formed on each photodiode, and an optically transparent layer having a different wavelength selectivity is provided on a light-receiving surface of each photodiode.

A method for making a photovoltaic device is provided that includes the steps of providing a silicon substrate having a complementary metal-oxide semiconductor (CMOS); bonding a first layer of silicon oxide to a second layer of silicon oxide wherein the bonded layers are deposited on the silicon substrate; and forming a III-V photovoltaic cell on a side of the bonded silicon oxide layers opposite the silicon substrate, wherein when the III-V photovoltaic cell is exposed to radiation, the III-V photovoltaic cell generates a current that powers a memory erasure device to cause an alteration of a memory state of a memory cell in an integrated circuit.