An image sensor includes a detection region, a first transistor region, and a second transistor region. The detection region including a first demodulation node and a second demodulation node generates a hole current in a substrate, and captures photocharges that are generated by incident light and move by the hole current. The first pixel transistor region including a plurality of transistors is disposed at one side of the detection region, and processes photocharges captured by the first demodulation node. The second pixel transistor region including a plurality of transistors is disposed at other side of the detection region, and processes photocharges captured by the second demodulation node.

An image sensor includes; a semiconductor substrate including a first surface and an opposing second surface, a pixel isolation structure in the semiconductor substrate and defining a pixel section, a photoelectric conversion region in the pixel section, a first device isolation layer on the pixel section and defining an active area on the first surface of the semiconductor substrate, a floating diffusion region in the active area and spaced apart from the photoelectric conversion region, a transfer gate electrode on the active area between the photoelectric conversion region and the floating diffusion region, and a second device isolation layer in the active area between the transfer gate electrode and the floating diffusion region.

An exemplary imaging device according to the present disclosure includes: an imaging region including a plurality of pixels; a peripheral region located outside of the imaging region; and a blockade region located between the imaging region and the peripheral region Each of the plurality of pixels includes a photoelectric conversion layer, a pixel electrode to collect a charge generated in the photoelectric conversion layer, and a first doped region electrically connected to the pixel electrode. In the peripheral region, a circuit to drive the plurality of pixels is provided. The blockade region includes a second doped region of a first conductivity type located between the imaging region and the peripheral region and a plurality of first contact plugs connected to the second doped region.

To provide a solid-state image sensor in which two or more semiconductor chips are bonded together without voids occurring in their bonding surfaces despite the conductive films bonded together at a high areal ratio. The solid-state image sensor includes at least a first semiconductor chip carrying thereon one or more than one of a first conductor and a pixel array, and a second semiconductor chip which bonds to the first semiconductor chip and carries thereon one or more than one of a second conductor and a logic circuit, with the first semiconductor chip and the second semiconductor chip bonding together in such a way that the first conductor and the second conductor overlap with each other and are electrically connected to each other, and the bonding occurring such that the first conductor and the second conductor differ from each other in the area of their bonding surfaces.

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.

To provide an imaging device that makes it possible to further increase imaging performance. This imaging device includes, in an effective pixel region extending along a first surface, a condensing optical system that condenses incident light, a photoelectric conversion unit configured to generate electric charge through photoelectric conversion; an electric charge holding unit configured to hold the electric charge transferred from the photoelectric conversion unit; and a first light shielding film that is provided between the photoelectric conversion unit and the electric charge holding unit in a thickness direction orthogonal to the first surface. The electric charge corresponds to an amount of the incident light passing through the condensing optical system. The first light shielding film blocks the incident light. Here, the condensing optical system condenses the incident light at a position in the effective pixel region. The position overlaps with the first light shielding film in the thickness direction

Image sensing devices according to present disclosure include metal gate structures in a pixel device. Particularly, the metal gate structures include a ferroelectric layer and a conductive layer to form a negative capacitance device in the gate stack. As a result, the transistors in the pixel device have reduced threshold swing, improved gain and reduced threshold voltage shift. The pixel device according to the present disclosure includes a combination of metal gate and polycrystalline gate, which provides flexibility in pixel device design and improves performance.

An image sensing device is provided to include: a substrate having a first surface on which light is incident and a second surface facing the first surface; a plurality of detection structures, each comprising a control node configured to exhibit a conductivity type and generate a potential gradient in the substrate, and a detection node configured to capture photocharge which is generated in response to incident light and migrates in response to the potential gradient; and a first well area disposed to abut the control nodes of the plurality of detection structures and containing an impurity with a different conductivity type from the conductivity type of the control nodes.

Disclosed is a light receiving element including an on-chip lens, a wiring layer, and a semiconductor layer disposed between the on-chip lens and the wiring layer. The semiconductor layer includes a photodiode, a first transfer transistor that transfers electric charge generated in the photodiode to a first charge storage portion, a second transfer transistor that transfers electric charge generated in the photodiode to a second charge storage portion, and an interpixel separation portion that separates the semiconductor layers of adjacent pixels from each other, for at least part of the semiconductor layer in the depth direction. The wiring layer has at least one layer including a light blocking member. The light blocking member is disposed to overlap with the photodiode in a plan view.

In some embodiments, a pixel sensor is provided. The pixel sensor includes a first photodetector arranged in a semiconductor substrate. A second photodetector is arranged in the semiconductor substrate, where a first substantially straight line axis intersects a center point of the first photodetector and a center point of the second photodetector. A floating diffusion node is arranged in the semiconductor substrate at a point that is a substantially equal distance from the first photodetector and the second photodetector. A pick-up well contact region is arranged in the semiconductor substrate, where a second substantially straight line axis that is substantially perpendicular to the first substantially straight line axis intersects a center point of the floating diffusion node and a center point of the pick-up well contact region.