Provided is a multilayer imaging device capable of both securing a wide sensitive region and securing an accumulated amount of charges. An imaging device according to an embodiment comprises a pixel, the pixel including a photoelectric conversion layer (15); a first electrode (11) positioned close to a first surface of the photoelectric conversion layer and electrically connected to the photoelectric conversion layer; a second electrode (16) positioned on a second surface opposite to the first surface of the photoelectric conversion layer; a charge accumulation electrode (12) disposed close to the first surface of the photoelectric conversion layer and spaced apart from the first electrode in a direction parallel to the first surface; and a third electrode (200) disposed at a position to have a portion overlapping a gap between the first electrode and the charge accumulation electrode in a direction perpendicular to the first surface.

An imaging device includes a first electrode, a charge accumulating electrode arranged with a space from the first electrode, an isolation electrode arranged with a space from the first electrode and the charge accumulating electrode and surrounding the charge accumulating electrode, a photoelectric conversion layer formed in contact with the first electrode and above the charge accumulating electrode with an insulating layer interposed therebetween, and a second electrode formed on the photoelectric conversion layer. The isolation electrode includes a first isolation electrode and a second isolation electrode arranged with a space from the first isolation electrode, and the first isolation electrode is positioned between the first electrode and the second isolation electrode.

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.

Pixels, such as for image sensors and electronic devices, include a photodiode formed in a semiconductor substrate, a floating diffusion, and a transfer structure selectively coupling the photodiode to the floating diffusion. The transfer structure includes a transfer gate formed on the semiconductor substrate, and a vertical channel structure including spaced apart first doped regions formed in the semiconductor substrate between the transfer gate and the photodiode. Each spaced apart first doped region is doped at a first dopant concentration with a first-type dopant. The spaced apart first doped regions are formed in a second doped region doped at a second dopant concentration with a second-type dopant of a different conductive type.

A solid-state imaging device includes a light-receiving surface, a plurality of pixels each including a photoelectric conversion section that photoelectrically converts light incident through the light-receiving surface, and a separation section that electrically and optically separates each photoelectric conversion section. Each of the pixels includes a charge-holding section that holds charges transferred from the photoelectric conversion section, a transfer transistor that includes a vertical gate electrode reaching the photoelectric conversion section, and transfers charges from the photoelectric conversion section to the charge-holding section, and a light-blocking section disposed in a layer between the photoelectric conversion section and the charge-holding section. A plurality of the vertical gate electrodes are electrically coupled together in a plurality of first pixels adjacent to each other among the plurality of pixels.

An image sensor includes a pixel array including first pixels and second pixels, each of the first and second pixels including photodiodes, a sampling circuit detecting a reset voltage and a pixel voltage from the first and second pixels and generating an analog signal, an analog-to-digital converter image data from the analog signal, and a signal processing circuit generating an image using the image data. Each of the first pixels includes a first conductivity-type well separating the photodiodes and having impurities of a first conductivity-type. The photodiodes have impurities of a second conductivity-type different from the first conductivity-type. Each of the second pixels includes a second conductivity-type well separating the photodiodes and having impurities of the second conductivity-type different from the first conductivity-type. A potential level of the second conductivity-type well is higher than a potential level of the first conductivity-type well.

Noise, color mixture, and the like are suppressed while reducing a restriction on layout disposition. An imaging apparatus includes a semiconductor substrate, a photoelectric conversion unit which is provided in the semiconductor substrate and generates charge corresponding to the amount of received light by photoelectric conversion, a charge holding unit which is disposed on a side closer to a first surface of the semiconductor substrate than to the photoelectric conversion unit, and holds the charge transferred from the photoelectric conversion unit, a charge transfer unit which transfers the charge from the photoelectric conversion unit to the charge holding unit, a vertical electrode which is disposed in a depth direction of the semiconductor substrate, the vertical electrode transmitting the charge generated by the photoelectric conversion unit to the charge transfer unit, and a first light control member which is disposed at a position overlapping the vertical electrode when the semiconductor substrate is seen in a plan view from a normal direction of the first surface, and is provided in a pixel region without straddling a boundary between pixels.

An imaging device including: a first semiconductor substrate; a second semiconductor substrate; and a wiring layer. The first semiconductor substrate has a first surface and a second surface and includes a sensor pixel. The second semiconductor substrate has a third surface and a fourth surface and includes a readout circuit that outputs a pixel signal based on an output from the sensor pixel. The second semiconductor substrate is stacked on the first semiconductor substrate with the first surface and the fourth surface opposed to each other. The wiring layer is between the first semiconductor substrate and the second semiconductor substrate and includes a first wiring line and a second wiring line that are electrically coupled to each other. One of the first wiring line and the second wiring line is in an electrically floating state while the other is electrically coupled to a transistor.

Improvement of noise characteristics is achievable. A solid-state imaging device according to an embodiment includes a plurality of photoelectric conversion elements (333) arranged in a two-dimensional grid shape in a matrix direction and each generating a charge corresponding to a received light amount, and a detection unit (400) that detects a photocurrent produced by the charge generated in each of the plurality of photoelectric conversion elements. A chip (201a) on which the photoelectric conversion elements are disposed and a chip (201b) on which at least a part of the detection unit is disposed are different from each other.

An image sensor includes: photodiodes arranged in a substrate; active pillars connected to the photodiodes and extending in a vertical direction perpendicular to a bottom surface of the substrate; at least two transistors stacked in the vertical direction, wherein portions of the active pillars are channel areas of the at least two transistors; a floating diffusion (FD) area disposed under a transfer transistor, which is one of the at least two transistors, wherein the FD area is configured to receive charge from the photodiode through the transfer transistor and the portions of the active pillars; and a light transmitting layer disposed on a top surface of the substrate.