Provided is a semiconductor device capable of achieving high detection efficiency and low jitter without depending on an increase in thickness of a substrate. A semiconductor device is provided with a plurality of pixels in each of which an avalanche photodiode element that photoelectrically converts incident light is formed, and each of the plurality of pixels is provided with a substrate including a first semiconductor material, and a stacked portion stacked on a surface on a light incident side of the substrate and including a second semiconductor material different from the first semiconductor material.

A plurality of subpixels is included in one pixel. An imaging device includes a subpixel, a pixel, and a pixel array. The subpixel includes a photoelectric conversion element that receives light incident at a predetermined angle and outputs an analog signal on the basis of intensity of the received light. The pixel includes a plurality of the subpixels, a lens that condenses light incident from an outside on the subpixel, and a photoelectric conversion element isolation portion that does not propagate information regarding intensity of the light acquired in the photoelectric conversion element to the adjacent photoelectric conversion element, and further includes a light-shielding wall that shields light incident on the lens of another pixel. The pixel array includes a plurality of the pixels.

It is possible to curb noise, color mixing, and the like. An imaging apparatus includes: a semiconductor; a photoelectric conversion unit that is provided on the semiconductor substrate and generates electrical charge in accordance with the amount of received light through photoelectric conversion; an electrical charge holding unit that is disposed on a side closer to a first surface of the semiconductor substrate than the photoelectric conversion unit and holds the electrical charge transferred from the photoelectric conversion unit; an electrical charge transfer unit that transfers the electrical charge from the photoelectric conversion unit to the electrical charge holding unit; a vertical electrode that transmits the electrical charge generated by the photoelectric conversion unit to the electrical charge transfer unit and is disposed in a depth direction of the semiconductor substrate, and a first light control unit that is disposed on a side closer to a second surface that is a side opposite to the first surface of the semiconductor substrate than the vertical electrode, is disposed at a position overlapping the vertical electrode in a plan view of the semiconductor substrate from a normal line direction of the first surface, and has a T-shaped section in the depth direction of the substrate. The first light control member includes a first light control portion and a second light control portion extending in mutually intersecting directions in an integrated structure.

Provided is a solid-state image sensor and an electronic device capable of suppressing the occurrence of a strong electrical field near a transistor while being compact. The solid-state image sensor includes a photoelectric conversion element that performs photoelectric conversion, an element isolation that penetrates from a first main surface to a second main surface of a substrate and that is formed between pixels including the photoelectric conversion element, and a conductive part provided in close contact with a first main surface side of the element isolation.

Disclosed herein is a semiconductor device, including: a first substrate including a first electrode, and a first insulating film configured from a diffusion preventing material for the first electrode and covering a periphery of the first electrode, the first electrode and the first insulating film cooperating with each other to configure a bonding face; and a second substrate bonded to and provided on the first substrate and including a second electrode joined to the first electrode, and a second insulating film configured from a diffusion preventing material for the second electrode and covering a periphery of the second electrode, the second electrode and the second insulating film cooperating with each other to configure a bonding face to the first substrate.

The present technique relates to a semiconductor device and an electronic appliance in which the reliability of the fine transistor can be maintained while the signal output characteristic is improved in a device formed by stacking semiconductor substrates. The semiconductor device includes a first semiconductor substrate, a second semiconductor substrate providing a function different from a function provided by the first semiconductor substrate, and a diffusion prevention film that prevents diffusion of a dangling bond terminating atom used for reducing the interface state of the first semiconductor substrate and the second semiconductor substrate, wherein at least two semiconductor substrates are stacked and the semiconductor substrates are electrically connected to each other, and the first semiconductor substrate and the second semiconductor substrate are stacked with the diffusion prevention film inserted between an interface of the first semiconductor substrate and an interface of the second semiconductor substrate.

A solid-state imaging device includes a photoelectric conversion unit, a light shielding unit and a transfer transistor. The photoelectric conversion unit generates charges by photoelectrically converting light. The light shielding unit is formed by engraving a semiconductor substrate on which the photoelectric conversion unit is formed, so as to surround an outer periphery of the photoelectric conversion unit. The transfer transistor transfers charges generated in the photoelectric conversion unit. During a charge accumulation period in which charges are accumulated in the photoelectric conversion unit, a potential that repels the charges is supplied to the light shielding unit and a gate electrode of the transfer transistor. During a charge transfer period in which charges are transferred from the photoelectric conversion unit, a potential that repels the charges is supplied to the light shielding unit and a potential that attracts the charges is supplied to the gate electrode of the transfer transistor.

There is provided a solid-state imaging device that includes a photoelectric conversion unit, a transfer gate, a floating diffusion unit, and a transistor. The photoelectric conversion unit produces a charge according to incident light. The transfer gate has a columnar shape having an opening that is continuous in a vertical direction, and transfers the charge from the photoelectric conversion unit. The floating diffusion unit is formed extending to a region surrounded by the opening of the transfer gate, and converts the transferred charge into a voltage signal. The transistor is electrically connected to the floating diffusion unit via a diffusion layer.

A semiconductor structure includes a substrate having a pixel array region and a first seal ring region, wherein the first seal ring region surrounds the pixel array region, and the first seal ring region includes a first seal ring. The semiconductor structure further includes a first isolation feature in the first seal ring region, wherein the first isolation feature is filled with a dielectric material, and the first isolation feature is a continuous structure surrounding the pixel array region. The semiconductor structure further includes a second isolation feature between the first isolation feature and the pixel array region, wherein the second isolation feature is filled with the dielectric material.

An image sensing device includes a first impurity region, a second impurity region, a floating diffusion region, and a transfer gate. The first impurity region is disposed in a semiconductor substrate and includes impurities with a first doping polarity, and the first impurity region generates photocharges by performing photoelectric conversion in response to incident light. The second impurity region is disposed over the first impurity region and has impurities with a second doping polarity different from the first doping polarity, and the second impurity region contacts with on some portions of the first impurity region. The floating diffusion region disposed over the second impurity region. The transfer gate couples to the floating diffusion region and transmits photocharges generated by the first impurity region to the floating diffusion region. The first impurity region is arranged not in contact with the transfer gate.