An apparatus according to the present invention in which a first substrate including a photoelectric conversion element and a gate electrode of a transistor, and a second substrate including a peripheral circuit portion are placed upon each other. The first substrate does not include a high-melting-metal compound layer, and the second substrate includes a high-melting-metal compound layer.

The present disclosure relates to a solid-state imaging device, a method for driving the solid-state imaging device, and an electronic device capable of improving auto-focusing accuracy by using a phase difference signal obtained by using a photoelectric conversion film. The solid-state imaging device includes a pixel including a photoelectric conversion portion having a structure where a photoelectric conversion film is interposed by an upper electrode on the photoelectric conversion film and a lower electrode under the photoelectric conversion film. The upper electrode is divided into a first upper electrode and a second upper electrode. The present disclosure can be applied to, for example, a solid-state imaging device or the like.

A circuit, including: a photodetector including a first readout terminal and a second readout terminal different than the first readout terminal; a first readout circuit coupled with the first readout terminal and configured to output a first readout voltage; a second readout circuit coupled with the second readout terminal and configured to output a second readout voltage; and a common-mode analog-to-digital converter (ADC) including: a first input terminal coupled with a first voltage source; a second input terminal coupled with a common-mode generator, the common-mode generator configured to receive the first readout voltage and the second readout voltage, and to generate a common-mode voltage between the first and second readout voltages; and a first output terminal configured to output a first output signal corresponding to a magnitude of a current generated by the photodetector.

An image sensor includes at least one image cell having a photodiode disposed in a substrate, a charge storage region disposed in the substrate to be spaced apart from the photodiode, a transfer gate electrode disposed on a channel region between the photodiode and the charge storage region to transfer a charge from the photodiode to the charge storage region, and a dummy pattern disposed on the substrate and configured to inhibit light from being introduced into the charge storage region from an adjacent image cell.

An imaging device having a semiconductor substrate that includes a first photoelectric converter, and a second photoelectric converter adjacent to the first photoelectric converter. The imaging device further includes a capacitive element one end of which is coupled to the first photoelectric converter, where the first capacitive element at least partly overlaps, in a plan view, with the second photoelectric converter.

An imaging element according to an embodiment of the present disclosure includes: a first electrode and a second electrode; a third electrode; a photoelectric conversion layer; and a semiconductor layer. The first electrode and the second electrode are disposed in parallel. The third electrode is disposed to be opposed to the first electrode and the second electrode. The photoelectric conversion layer is provided between the first electrode and second electrode and the third electrode. The semiconductor layer is provided between the first electrode and second electrode and the photoelectric conversion layer. The semiconductor layer has a first layer and a second layer stacked therein in order from the photoelectric conversion layer side. The second layer has an energy level at a lowest edge of a conduction band that is shallower than an energy level of the first layer at a lowest edge of a conduction band.

A solid-state imaging element that includes a semiconductor layer, a floating diffusion region (FD), a penetrating pixel separation region, and a non-penetrating pixel separation region. In the semiconductor layer, a visible-light pixel (PDc) that receives visible light and an infrared-light pixel (PDw) that receives infrared light are two-dimensionally arranged. The floating diffusion region is provided in the semiconductor layer and is shared by adjacent visible-light and infrared-light pixels. The penetrating pixel separation region is provided in a region excluding a region corresponding to the floating diffusion region in an inter-pixel region of the visible-light pixel and the infrared-light pixel, and penetrates the semiconductor layer in a depth direction. The non-penetrating pixel separation region is provided in the region corresponding to the floating diffusion region in the inter-pixel region, and reaches a midway part in the depth direction from the light receiving surface of the semiconductor layer.

A solid-state imaging device includes a plurality of pixels, each of the plurality of pixels including a photoelectric converter. The photoelectric converter includes a first semiconductor region of a first conductivity type, a second semiconductor region of a second conductivity type provided under the first semiconductor region, and a third semiconductor region of the first conductivity type provided under the second semiconductor region. The second semiconductor region has a first end portion and a second end portion opposing to the first end portion. The third semiconductor region has a first region and a second region overlapping with the second semiconductor region in a plan view, and the first region and the second region are spaced apart from each other from a part of the first end portion to a part of the second end portion.

The present technology relates to an imaging element and an electronic device capable of preventing light from leaking into an adjacent pixel. A semiconductor layer in which a first pixel in which a read pixel signal is used to generate an image, and a second pixel in which the read pixel signal is not used to generate an image are arranged, and a wiring layer stacked on the semiconductor layer are provided, and a structure of the first pixel and a structure of the second pixel are different. A first inter-pixel separation portion that separates the semiconductor layer of the adjacent first pixels, and a second inter-pixel separation portion that separates the semiconductor layer of the adjacent second pixels are further provided, and the first inter-pixel separation portion and the second inter-pixel separation portion are provided with different structures. The present technology can be applied to an imaging element in which dummy pixels are arranged.

A solid-state imaging element of a pixel sharing type with improved driving of transistors is disclosed. A first electric charge accumulating section and a second electric charge accumulating section are arranged in a predetermined direction. A first transfer section transfers electric charge from first photoelectric conversion elements to the first electric charge accumulating section, causing it to accumulate the electric charge. A second transfer section transfers electric charge from second photoelectric conversion elements to the second electric charge accumulating section, causing it to accumulate the electric charge. A first transistor is configured to output a signal corresponding to an amount of the electric charge accumulated in each of the first electric charge accumulating section and the second electric charge accumulating section. A second transistor is arranged with the first transistor in the predetermined direction and connected in parallel to the first transistor.