Provided is a solid-state imaging device including a lamination-type backside illumination CMOS (Complementary Metal Oxide Semiconductor) image sensor having a global shutter function. The solid-state imaging device includes a separation film including one of a light blocking film and a light absorbing film between a memory and a photo diode.

The present disclosure relates to a solid-state image pickup device, a manufacturing method, and an electronic apparatus, which can obtain high charge transfer efficiency from a photoelectric conversion unit to a floating diffusion layer. The floating diffusion layer is arranged in a rectangular shape so as to surround a gate electrode of a vertical transistor whose groove portion is rectangular. A reset drain is formed so as to be adjacent to the floating diffusion layer through a reset gate. A potential of the floating diffusion layer is reset to the same potential as that of the reset drain by applying a predetermined voltage to the reset gate. It is possible to apply the present disclosure to, for example, a CMOS solid-state image pickup device used in an image pickup device such as a camera.

A back-illuminated type solid-state image pickup device (1041) includes read circuits (Tr1, Tr2) formed on one surface of a semiconductor substrate (1042) to read a signal from a photo-electric conversion element (PD) formed on the semiconductor substrate (1042), in which electric charges (e) generated in a photo-electric conversion region (1052c1) formed under at least one portion of the read circuits (Tr1, Tr2) are collected to an electric charge accumulation region (1052a) formed on one surface side of the semiconductor substrate (1042) of the photo-electric conversion element (PD) by electric field formed within the photo-electric conversion element (PD). Thus, the solid-state image pickup device and the camera are able to make the size of pixel become very small without lowering a saturation electric charge amount (Qs) and sensitivity.

An image sensor includes a control circuit and pixels. Each pixel includes: a photosensitive area, a substantially rectangular storage area adjacent to the photosensitive area, and a read area. First and second insulated vertical electrodes electrically connected to each other are positioned opposite each other and delimit the storage area. The first electrode extends between the storage area and the photosensitive area. The second electrode includes a bent extension opposite a first end of the first electrode, with the storage area emerging onto the photosensitive area on the side of the first end. The control circuit operates to apply a first voltage to the first and second electrodes to perform a charge transfer, and a second voltage to block said transfer.

Provided is a method of fabricating an image sensor device. An exemplary includes forming a plurality of radiation-sensing regions in a substrate. The substrate has a front surface, a back surface, and a sidewall that extends from the front surface to the back surface. The exemplary method further includes forming an interconnect structure over the front surface of the substrate, removing a portion of the substrate to expose a metal interconnect layer of the interconnect structure, and forming a bonding pad on the interconnect structure in a manner so that the bonding pad is electrically coupled to the exposed metal interconnect layer and separated from the sidewall of the substrate.

An imaging apparatus includes a scanning circuit configured to perform shutter scanning and readout scanning, a first control unit configured to control the capacitance setting unit to set a capacitance value of the input node in the readout scanning, and a second control unit configured to control the capacitance setting unit to set a capacitance value of the input node in the shutter scanning.

A photoelectric conversion apparatus includes a first substrate having a first semiconductor device layer including a plurality of photoelectric conversion units and a well, and a second substrate having a second semiconductor device layer including a circuit configured to process signals obtained by the plurality of photoelectric conversion units, wherein the first and second substrates are laminated together, wherein the first semiconductor device layer includes an effective pixel region, an optical black pixel region, and an outer periphery region, wherein, in a planar view, a light-blocking region formed by a light-blocking layer overlaps the optical black pixel region, and the light-blocking region does not overlap the outer periphery region, wherein the outer periphery region has a charge draining region including a semiconductor region of the same conductivity type as a signal charge, and wherein a fixed potential is supplied to the charge draining region.

A light-receiving device according to an embodiment of the present disclosure includes: a first substrate including a plurality of photoelectric conversion sections that photoelectrically converts light and an accumulation section that accumulates electric charge photoelectrically converted by the photoelectric conversion sections; a second substrate stacked on the first substrate and including a readout circuit that outputs a first signal based on the electric charge accumulated in the accumulation section; and a wiring layer including a via that electrically couples the accumulation section and the readout circuit to each other. The first substrate and the second substrate are stacked to allow a first surface of the first substrate on which an element is formed and a second surface of the second substrate on which an element is formed to be opposed to each other. The via penetrates a plurality of layers in the wiring layer.

An imaging device that smoothly transfers electric charges from a photoelectric converter to a transfer destination is provided. This imaging device includes: a semiconductor layer; a photoelectric converter that generates electric charges corresponding to a received light amount; and a transfer section that includes a first trench gate and a second trench gate and transfers the electric charges from the photoelectric converter to a single transfer destination via the first trench gate and the second trench gate, the first trench gate and the second trench gate each extending from the front surface to the back surface of the semiconductor layer into the photoelectric converter. The first trench gate has a first length from the front surface to the photoelectric converter, and the second trench gate has a second length from the front surface to the photoelectric converter, the second length being shorter than the first length.

A camera system including an optical system; and an imaging device that receives a light through the optical system. The imaging device includes a semiconductor substrate; pixels; and a signal line located along the pixels. Each pixel includes a photoelectric converter that generates signal charge by photoelectric conversion, a first transistor that outputs a signal to the signal line according to an amount of the signal charge, and a circuit that is coupled to a gate of the first transistor and that includes a capacitive element and a second transistor. The signal line is positioned in proximity to the semiconductor. The capacitive element is further away from the semiconductor substrate compared to the signal line. The gate of the first transistor is coupled to the capacitive element through the second transistor, and the gate of the first transistor is coupled to the photoelectric converter not through the second transistor.