A solid-state imaging device (200) includes a photoelectric conversion device (211), a current-voltage conversion circuit (310), and an output circuit. The photoelectric conversion device (211) performs photoelectric conversion of incident light. The current-voltage conversion circuit (310) includes a first transistor (311) that converts an amount of electric charge generated by photoelectric conversion into a voltage signal. The output circuit includes a second transistor having an S value smaller than an S value of the first transistor (311) and generates an output signal based on the voltage signal.

In some embodiments, a photodetector is provided. The photodetector includes a first well having a first doping type disposed in a semiconductor substrate. A second well having a second doping type opposite the first doping type is disposed in the semiconductor substrate on a side of the first well. A first doped buried region having the second doping type is disposed in the semiconductor substrate, where the first doped buried region extends laterally through the semiconductor substrate beneath the first well and the second well. A second doped buried region having the second doping type is disposed in the semiconductor substrate and vertically between the first doped buried region and the first well, where the second doped buried region contacts the first well such that a photodetector p-n junction exists along the second doped buried region and the first well.

A semiconductor device having a structure which can prevent a decrease in electrical characteristics due to miniaturization is provided. The semiconductor device includes, over an insulating surface, a stack in which a first oxide semiconductor layer and a second oxide semiconductor layer are sequentially formed, and a third oxide semiconductor layer covering part of a surface of the stack. The third oxide semiconductor layer includes a first layer in contact with the stack and a second layer over the first layer. The first layer includes a microcrystalline layer, and the second layer includes a crystalline layer in which c-axes are aligned in a direction perpendicular to a surface of the first layer.

Provided is a conversion apparatus including a pixel including an avalanche diode and a circuit configured to process a signal according to an output of the avalanche diode, and an output unit configured to output data according to an output signal of the pixel, in which the output unit includes a first circuit and a second circuit configured to operate at a speed faster than a speed of the first circuit, and an absolute value of a threshold voltage of a first transistor which constitutes the first circuit is larger than an absolute value of a threshold voltage of a second transistor which constitutes the second circuit.

A purpose of the present invention is to countermeasure a connection failure of an electrode in an optical sensor using PIN type photo conductive film. A structure of the present invention is as follows. A semiconductor device including an optical sensor, the optical sensor including: a thin film transistor formed on a substrate, and a photo diode formed above the thin film transistor, in which the photo diode includes an anode, a photo conductive film and a cathode, the cathode is constituted from a titanium film, and a first transparent conductive film is formed between the titanium film and the photo conductive film.

A 3D CMOS image sensor is provided in the present invention, including a semiconductor substrate, a photodiode and a well formed in the semiconductor substrate, a shallow trench isolation (STI) layer formed on a front surface of the semiconductor substrate, a fin protruding upwardly from the semiconductor substrate through the STI layer, wherein the fin is composed of the photodiode and the well, a first gate spanning the photodiode portion and the well portion abutting the photodiode portion of the fin to constitute a transfer transistor, a second gate spanning in the middle of the well portion of the fin to constitute a reset transistor, and a floating diffusion region in the well portion of the fin between the first gate and the second gate electrically connecting the transfer transistor and the reset transistor.

A touch screen panel using a thin film transistor (TFT) photodetector includes a touch panel including at least one unit pattern for sensing light reflected by a touch by using a TFT photodetector including an active layer formed of amorphous silicon or polycrystalline silicon on an amorphous transparent material, and a controller configured to scan the at least one unit pattern and read touch coordinates as a result of the scanning.

A pixel sensor includes a transfer fin field effect transistor (finFET) to transfer a photocurrent from a photodiode to a drain region. The transfer finFET includes at least a portion of the photodiode, an extension region associated with the drain region, a plurality of channel fins, and a transfer gate at least partially surrounding the channel fins to control the operation of the transfer finFET. In the transfer finFET, the transfer gate is wrapped around (e.g., at least three sides) of each of the channel fins, which provides a greater surface area over which the transfer gate is enabled to control the transfer of electrons. The greater surface area results in greater control over operation of the finFET, which may reduce switching times of the pixel sensor (which enables faster pixel sensor performance) and may reduce leakage current of the pixel sensor relative to a planar transfer transistor.

A solid-state imaging element of an embodiment of the present disclosure includes: a semiconductor substrate including a photoelectric conversion section for each pixel; a pixel transistor provided on one surface of the semiconductor substrate; and an element separation section provided in the semiconductor substrate and including a first element separation section and a second element separation section that have mutually different configurations, the element separation section defining an active region of the pixel transistor, in which the second element separation section has, on a side surface, a first semiconductor region and a second semiconductor region that have mutually different impurity concentrations in a depth direction of the second element separation section.

The present disclosure provides a photoelectric detector and an electronic device. The photoelectric detector has a pixel region and a peripheral region surrounding the pixel region, includes a base substrate and a plurality of pixel units arranged on the base substrate and positioned in the pixel region; each pixel unit includes a thin film transistor, a photodiode and a storage capacitor; for each pixel unit, a first electrode of the thin film transistor is connected with a first electrode of the photodiode and a first electrode plate of the storage capacitor, a second electrode of the photodiode is connected with a first bias signal line, a second electrode plate of the storage capacitor is connected with a second bias signal line, the first bias signal line is electrically connected with the second bias signal line at a connection node located in the peripheral region.