A solid-state imaging device capable of weakening incident light that passes through an effective pixel region and enters an optical black pixel region. Among a plurality of straight groove portions constituting a trench portion, a first straight groove portion is formed at a boundary between an effective pixel region and an optical black pixel region (OPB pixel region), a plurality of second straight groove portions are formed in the OPB pixel region and parallel to the boundary in a plan view, and a third straight groove portion is formed between photoelectric conversion units in the effective pixel region, a specific straight groove portion, the specific straight groove portion being the first groove portion and/or being one or more of the plurality of second straight groove portions, has a different shape from the third straight groove portion, and a light shielding material is embedded in the specific straight groove portion.

According to one embodiment, a display device includes a first substrate, a second substrate, a liquid crystal layer and an illumination device. The first substrate includes a base, a sensor, a sensor circuit and a sensor light-shielding layer. The sensor is located between the base and the liquid crystal layer in a display area that includes pixels, and outputs a detection signal corresponding to light becoming incident from a side of the liquid crystal layer. The sensor circuit includes a switching element and is connected to the sensor. The sensor light-shielding layer is opposed to a channel area formed in a semiconductor layer included in the switching element, and blocks light from the illumination device on the channel area.

Photo-emitting and/or photo-receiving diode array device, comprising: a stack of first and second semiconductor layers doped according to different types; first trenches passing through the stack and surrounding a region of the stack wherein several diodes are formed; dielectric portions arranged in the first trenches and covering lateral flanks of said region over the entire thickness of the second layer and a first part of the thickness of the first layer; first electrically conductive portions arranged in the first trenches and covering the lateral flanks of said region over a second part of the thickness of the first layer, and forming first electrodes of the diodes of said region; at least one second trench partially passing through the first layer and separating the portions of the first layer from the diodes of said region.

A solid-state imaging device having a backside illuminated structure, includes: a pixel region in which pixels each having a photoelectric conversion portion and a plurality of pixel transistors are arranged in a two-dimensional matrix; an element isolation region isolating the pixels which is provided in the pixel region and which includes a semiconductor layer provided in a trench by an epitaxial growth; and a light receiving surface at a rear surface side of a semiconductor substrate which is opposite to a multilayer wiring layer.

Image sensors are provided. The image sensors may include a substrate including first, second, third and fourth regions, a first photoelectric conversion element in the first region, a second photoelectric conversion element in the second region, a third photoelectric conversion element in the third region, a fourth photoelectric conversion element in the fourth region, a first microlens at least partially overlapping both the first and second photoelectric conversion elements, and a second microlens at least partially overlapping both the third and fourth photoelectric conversion elements. The image sensors may also include a floating diffusion region and first, second and third pixel transistors configured to perform different functions from each other. Each of the first, second and third pixel transistors may be disposed in at least one of first, second, third and fourth pixel regions. The first pixel transistor may include multiple first pixel transistors.

A depth sensor includes a first pixel including a plurality of first photo transistors each receiving a first photo gate signal, a second pixel including a plurality of second photo transistors each receiving a second photo gate signal, a third pixel including a plurality of third photo transistors each receiving a third photo gate signal, a fourth pixel including a plurality of fourth photo transistors each receiving a fourth photo gate signal, and a photoelectric conversion element shared by first to fourth photo transistors of the plurality of first to fourth photo transistors.

Photosensors may be formed on a front side of a semiconductor substrate. An optical refraction layer having a first refractive index may be formed on a backside of the semiconductor substrate. A grid structure including openings is formed over the optical refraction layer. A masking material layer is formed over the grid structure and the optical refraction layer. The masking material layer may be anisotropically etched using an anisotropic etch process that collaterally etches a material of the optical refraction layer and forms non-planar distal surface portions including random protrusions on physically exposed portions of the optical refraction layer. An optically transparent layer having a second refractive index that is different from the first refractive index may be formed on the non-planar distal surface portions of the optical refraction layer. A refractive interface refracts incident light in random directions, and improves quantum efficiency of the photosensors.

A solid-state image capturing device according to the present disclosure includes an image capturing element, a light transmitting member, a support member, a sealing resin member, and a wall member. The image capturing element is mounted on a substrate. The support member is arranged in a part of an outer-peripheral portion of the image capturing element, the outer-peripheral portion surrounding a light receiving unit of the image capturing element. The light transmitting member is supported by the support member. The sealing resin member is arranged in a peripheral portion of the image capturing element. The wall member is provided between the sealing resin member and a part of the outer-peripheral portion of the image capturing element, the part excluding a part in which the support member is arranged.

An image sensor includes: a pixel substrate that includes a plurality of pixels each having a photoelectric conversion unit that generates an electric charge through photoelectric conversion executed on light having entered therein and an output unit that generates a signal based upon the electric charge and outputs the signal; and an arithmetic operation substrate that is laminated on the pixel substrate and includes an operation unit that generates a corrected signal by using a reset signal generated after the electric charge in the output unit is reset and a photoelectric conversion signal generated based upon an electric charge generated in the photoelectric conversion unit and executes an arithmetic operation by using corrected signals each generated in correspondence to one of the pixels.

An image sensor includes first pixels and second pixels. The second pixels of the image sensor are distinct from the first pixels of the image sensor.