The present invention has an object of improving the operation stability of a semiconductor device that detects radiations without decreasing the yield thereof. A semiconductor device includes an active matrix substrate (50) including a plurality of TFTs (10) and a plurality of pixel electrode (20); a photoelectric conversion substrate (62) located to face the active matrix substrate (50); an upper electrode (64) provided on a surface of the photoelectric conversion substrate (62) opposite to the active matrix substrate (50); and a plurality of connection electrodes (72) provided between the active matrix substrate (50) and the photoelectric conversion substrate(62), the plurality of connection electrodes (72) being formed of metal material. Each of the plurality of connection electrodes (72) is in direct contact with any of the plurality of pixel electrodes (20) and with the photoelectric conversion substrate (62), overlaps a semiconductor layer (14) of any of the plurality of TFTs (10) as seen in a direction normal to the active matrix substrate (50), and contains a metal element having an atomic number of 42 or greater and 82 or smaller.

A solid-state imaging device includes: a first electrode formed above a semiconductor substrate; a photoelectric conversion film formed on the first electrode and for converting light into signal charges; a second electrode formed on the photoelectric conversion film; a charge accumulation region electrically connected to the first electrode and for accumulating the signal charges converted from the light by the photoelectric conversion film; a reset gate electrode for resetting the charge accumulation region; an amplification transistor for amplifying the signal charges accumulated in the charge accumulation region; and a contact plug in direct contact with the charge accumulation region, comprising a semiconductor material, and for electrically connecting to each other the first electrode and the charge accumulation region.

A solid-state image pickup unit includes: a substrate made of a first semiconductor; a substrate made of a first semiconductor; a photoelectric conversion device provided on the substrate and including a first electrode, a photoelectric conversion layer, and a second electrode in order from the substrate; and a plurality of field-effect transistors configured to perform signal reading from the photoelectric conversion device. The plurality of transistors include a transfer transistor and an amplification transistor, the transfer transistor includes an active layer containing a second semiconductor with a larger band gap than that of the first semiconductor, and one terminal of a source and a drain of the transfer transistor also serves the first electrode or the second electrode of the photoelectric conversion device, and the other terminal of the transfer transistor is connected to a gate of the amplification transistor.

A photoelectric conversion device includes a photoelectric conversion unit disposed above a substrate and a reading circuit. The photoelectric conversion unit includes a first electrode disposed above the substrate, a second electrode disposed above the first electrode, and a photoelectric conversion film disposed between the first electrode and the second electrode. The second electrode includes an opening, and is disposed in contact with the photoelectric conversion film at a boundary between adjacent photoelectric conversion units. An insulating film is disposed in contact with the second electrode.

A semiconductor device includes a first semiconductor layer of a first conductivity type having a primary surface on one side thereof and a secondary surface on an opposite side thereof, and having a sensor therein, a second semiconductor layer of a second conductivity type having a circuit element formed therein, the second semiconductor layer being formed at said one side of the primary surface of the first semiconductor layer, an insulating layer formed between the first semiconductor layer and the second semiconductor layer, and being disposed on the primary surface of the first semiconductor layer, and a charge-attracting semiconductor layer of the first conductivity type configured to attract electrical charges generated in the insulating layer when a fixed voltage is supplied to the charge-attracting semiconductor layer.

An imaging device including: pixel cells each comprising: a photoelectric converter including two electrodes and a photoelectric conversion layer therebetween; a field effect transistor having a gate and a channel region; and a node between the photoelectric converter and the field effect transistor. The field effect transistor outputs an electric signal corresponding to change in dielectric constant between the electrodes, the change being caused by incident light on the photoelectric conversion layer. Cpd1, Cn1, Cpd2 and Cn2 satisfy a relation of Cpd1/Cn1<Cpd2/Cn2 where a capacitance value of a first photoelectric converter in a state of receiving no incident light is Cpd1, a capacitance value between a first node and a first channel region is Cn1, a capacitance value of a second photoelectric converter in a state of receiving no incident light is Cpd2, and a capacitance value between a second node and a second channel region is Cn2.

Various embodiment include optical and optoelectronic devices and methods of making same. Under one aspect, an optical device includes an integrated circuit having an array of conductive regions, and an optically sensitive material over at least a portion of the integrated circuit and in electrical communication with at least one conductive region of the array of conductive regions. Under another aspect, a film includes a network of fused nanocrystals, the nanocrystals having a core and an outer surface, wherein the core of at least a portion of the fused nanocrystals is in direct physical contact and electrical communication with the core of at least one adjacent fused nanocrystal, and wherein the film has substantially no defect states in the regions where the cores of the nanocrystals are fused. Additional devices and methods are described.

Provided is a solid-state image pickup device that makes it possible to enhance image quality, and a manufacturing method thereof, and an electronic apparatus. A solid-state image pickup device includes a pixel section that includes a plurality of pixels, the pixels each including one or more organic photoelectric conversion sections, wherein the pixel section includes an effective pixel region and an optical black region, and the organic photoelectric conversion sections of the optical black region include a light-shielding film and a buffer film on a light-incidence side.

A semiconductor device includes a first semiconductor layer of a first conductivity type having a primary surface and having a sensor therein, a second semiconductor layer of a second conductivity type having a circuit element formed therein. The second semiconductor layer is formed at a same side of the primary surface of the first semiconductor layer. The device further includes an insulating layer formed between the first semiconductor layer and the second semiconductor layer. The insulating layer is disposed on the primary surface of the first semiconductor layer and surrounds the circuit element, and includes a charge-attracting semiconductor pattern of the first conductivity type that is disposed near the circuit element so as to attract electrical charges generated in the insulating layer.

An imaging device with excellent imaging performance is provided. An imaging device that easily performs imaging under a low illuminance condition is provided. A low power consumption imaging device is provided. An imaging device with small variations in characteristics between its pixels is provided. A highly integrated imaging device is provided. A photoelectric conversion element includes a first electrode, and a first layer, a second layer, and a third layer. The first layer is provided between the first electrode and the third layer. The second layer is provided between the first layer and the third layer. The first layer contains selenium. The second layer contains a metal oxide. The third layer contains a metal oxide and also contains at least one of a rare gas atom, phosphorus, and boron. The selenium may be crystalline selenium. The second layer may be a layer of an InGaZn oxide including c-axis-aligned crystals.