Abstract: The present disclosure provides a display substrate, a method for preparing the same, and a display device. The display substrate includes: a base substrate; a display function layer located on the base substrate, a first groove arranged in the first surface, and a first connection sub-line located in the first groove and covering a bottom and each side wall of the first groove, the first connection sub-line being connected to a signal input terminal; an integrated circuit located on a second surface, a second groove arranged in the second surface, and a second connection sub-line located in the second groove, the second connection sub-line being connected to the first connection sub-line and a signal output terminal of the integrated circuit.

Abstract: Solid-state imaging devices, methods of producing a solid-state imaging device, and electronic apparatuses are provided. More particularly, a solid-state image device includes a silicon substrate, and at least a first photodiode formed in the silicon substrate. The device also includes an epitaxial layer with a first surface adjacent a surface of the silicon substrate, and a transfer transistor with a gate electrode that extends from the at least a first photodiode to a second surface of the epitaxial layer opposite the first surface. In further embodiments, a solid-state imaging device with a plurality of pixels formed in a second semiconductor substrate wherein the pixels are symmetrical with respect to a center point is provided. A floating diffusion is formed in an epitaxial layer, and a plurality of transfer gate electrodes that are each electrically connected to the floating diffusion by one of the transfer gate electrodes is provided.

Abstract: An SiPM sensor chip includes pixels consisting of microcells Z, each pixel being associated with an xy position x1, x2, x3, . . . , xN or y1, y2, y3, . . . yM. A plurality of pixels form a block, and the microcells are connected to output channels for a linear coding.

Abstract: The present disclosure discloses an anti-reflection coating and a method of forming the same. According to one embodiment of the present disclosure, the anti-reflection coating includes a first layer positioned on a substrate to be spaced apart from the substrate by a first distance and a second layer positioned on the first layer to be spaced apart from the first layer by a second distance. In this case, the first and second layers are a metamaterial forming a structural double layer and are realized as an anomalous dispersive medium that does not absorb incident light. The structural double layer may realize spatiotemporal dispersion that varies depending on an incidence angle using the nonlocality of the electromagnetic wave reaction of incident light.

Abstract: In some embodiments, a method is provided. The method includes forming a plurality of trenches in a semiconductor substrate, where the trenches extend into the semiconductor substrate from a back-side of the semiconductor substrate. An epitaxial layer comprising a dopant is formed on lower surfaces of the trenches, sidewalls of the trenches, and the back-side of the semiconductor substrate, where the dopant has a first doping type. The dopant is driven into the semiconductor substrate to form a first doped region having the first doping type along the epitaxial layer, where the first doped region separates a second doped region having a second doping type opposite the first doping type from the sidewalls of the trenches and from the back-side of the semiconductor substrate. A dielectric layer is formed over the back-side of the semiconductor substrate, where the dielectric layer fill the trenches to form back-side deep trench isolation structures.

Abstract: Various structures of image sensors are disclosed, as well as methods of forming the image sensors. According to an embodiment, a structure comprises a substrate comprising photo diodes, an oxide layer on the substrate, recesses in the oxide layer and corresponding to the photo diodes, a reflective guide material on a sidewall of each of the recesses, and color filters each being disposed in a respective one of the recesses. The oxide layer and the reflective guide material form a grid among the color filters, and at least a portion of the oxide layer and a portion of the reflective guide material are disposed between neighboring color filters.

Abstract: In some embodiments, the present disclosure relates to an image sensor, including a first photodiode and a second photodiode disposed in a semiconductor substrate. A floating diffusion node is disposed along a frontside of the semiconductor substrate and between the first and second photodiodes. A partial backside deep trench isolation (BDTI) structure is disposed within the semiconductor substrate and between the first and second photodiodes. The partial BDTI extends from a backside of the semiconductor substrate and is spaced from the floating diffusion node. A full BDTI structure extends from the backside of the semiconductor substrate to the frontside of the semiconductor substrate.

Abstract: A semiconductor device including a first semiconductor section including a first wiring layer at one side thereof, the first semiconductor section further including a photodiode, a second semiconductor section including a second wiring layer at one side thereof, the first and second semiconductor sections being secured together, a third semiconductor section including a third wiring layer at one side thereof, the second and the third semiconductor sections being secured together such the first semiconductor section, second semiconductor section, and the third semiconductor section are stacked together, and a first conductive material electrically connecting at least two of (i) the first wiring layer, (ii) the second wiring layer, and (iii) the third wiring layer such that the electrically connected wiring layers are in electrical communication.

Abstract: A solid-state imaging device is provided. The solid-state imaging device includes an imaging region having a plurality of pixels arranged in a two-dimensional array, in which the imaging region includes an effective pixel and a black reference pixel; and a shape of a floating diffusion portion in the effective pixel is different from that of a floating diffusion portion in the black reference pixel.

Abstract: A photosensitive sensor and a method of manufacturing the photosensitive sensor are disclosed. The photosensitive sensor includes a thin film transistor and a photosensitive element on a substrate, wherein the photosensitive element includes a first electrode, a second electrode, and a photosensitive layer between the first electrode and the second electrode. The second electrode is connected to a drain electrode of the thin film transistor. An orthographic projection of an active layer of the thin film transistor on the substrate is within an orthographic projection of the second electrode on the substrate. The second electrode includes at least two stacked conductive layers, at least one of the at least two stacked conductive layers being a light shielding metal layer.

Abstract: An image acquisition unit acquires first and second radiographic images acquired by irradiating a first radiation detector and a second radiation detector which overlaps the first radiation detector so as to deviate from the first radiation detector by a half pixel with radiation which has been emitted from a radiation source and transmitted through an object. A corresponding positional relationship acquisition unit acquires a corresponding positional relationship between the position of pixels of the first radiographic image and the position of pixels of the second radiographic image. A resolution enhancement unit estimates a pixel value corresponding to a position between the pixels of the first radiographic image, on the basis of the corresponding positional relationship, a pixel value of the first radiographic image, and a pixel value of the second radiographic image, and generates a processed radiographic image having a higher resolution than the first and second radiographic images.

Abstract: According to an aspect of the present invention, provided is a solid state imaging device including a plurality of pixels, and each of the pixels has a charge accumulation region of a first conductivity type that accumulates signal charges corresponding to an incident light, a drain region of the first conductivity type to which a predetermined voltage is applied, a drain gate located between the drain region and the charge accumulation region in a planar view, and a semiconductor region of the first conductivity type connected to the charge accumulation region and the drain region.

Abstract: Example embodiments relate to an image sensor and a method for read-out of pixel signal. One embodiment includes an image sensor. The image sensor includes an array of pixels for detecting light incident on the pixel. The image sensor also includes an in-pixel correlated double sampling (CDS) circuitry. The image sensor also includes a column line that extends along and is associated with a column of pixels in the array of pixels. The column line is configured to selectively receive a pixel signal from a pixel in the column. Further, the image sensor includes a voltage-drop correction line that extends along and is associated with the column of pixels. The voltage-drop correction line is configured to provide a correction voltage signal to a pixel in the column such that corrects for voltage drop of the pixel signal in read-out through the column line.

Abstract: A method of fabricating a photovoltaic cell having a microinverter is provided. The method may include fabricating a monolithic microinverter layer through epitaxy and operably connecting the at least one microinverter layer to at least one photovoltaic cell formed on a photovoltaic layer. A photovoltaic device is also provided. The device may have a photovoltaic layer comprising at least one photovoltaic cell and a microinverter layer comprising at least one microinverter, wherein the microinverter layer was fabricated through epitaxy, the at least one microinverter is configured to be operably connected to at least one photovoltaic cell.

Abstract: An image sensor chip may include a first sub-chip, a second sub-chip on the first sub-chip, and an interconnector between the first and second sub-chips. The first sub-chip may include a first substrate, a bottom electrode on a first region of the first substrate, and a first capacitor on the bottom electrode. The first capacitor may include a plurality of first electrodes vertically extending from a top surface of the bottom electrode, a second electrode on the first electrodes, and a first dielectric layer between the second electrode and the first electrodes. The second sub-chip may include a pixel array configured to convert incident light into an electrical signal. The pixel array may be electrically connected through the interconnector to the first capacitor.

Abstract: A solid-state image pickup device is provided which can inhibit degradation of image quality which may occur when a global electronic shutter operation is performed. A gate drive line for a first transistor of gate drive lines for pixel transistors is positioned in proximity to a converting unit.

Abstract: An image sensor packaging method, an image sensor package and a lens module are disclosed. In the image sensor packaging method, plural image sensor dies are formed within a molded layer, resulting in a package with a significantly reduced thickness which is favorable to the slimming of the package. The packaging method does not involve any wire bonding process. Instead, metal pads are led out through a thin metal film formed in non-photosensitive areas on the same side of micro lens surfaces of the image sensor dies. This approach has a less adverse impact on micro lens surfaces and, compared to the wire bonding process, allows a smaller spacing from metal pads to the micro lens surfaces with respect to a direction parallel to the micro lens surfaces, which enables more compact image sensor dies usable in a lens module for an optimized spatial design and ease of miniaturization.

Abstract: A semiconductor device having a substrate with at least one photo-detecting region and at least one bond pad is provided. A first passivation layer is deposited over the substrate and over step portions at the edges of the bond pad and a trench having sidewalls and a bottom surface is formed in the substrate. A light shielding layer is deposited over the first passivation layer and covering the trench sidewalls. The light shielding layer has end portions at the photo-detecting region, at step portions at the edges of the bond pad and at the bottom surface of the trench. A second passivation layer is deposited over the light shielding layer. A third passivation layer is deposited over the end portions of the light shielding layer at the photo-detecting region and at the step portions at edges of the bond pad.

Abstract: The present technology relates to a solid-state imaging element, an imaging device, and an electronic device that can improve transfer efficiency of a charge accumulation unit (MEM) and can increase the number of saturation electrons Qs. In a case where a charge voltage conversion unit (FD) is connected to a center of a charge accumulation unit (MEM) in each pixel and pixels are arrayed in an array, a column in which photoelectric conversion units (PD) are arrayed and a column including charge voltage conversion units (FD) and pixel transistors are arrayed in parallel. The present technology can be applied to a CMOS image sensor.

Abstract: An imaging device comprises a sensor substrate including a pixel array that includes at least a first pixel. The first pixel includes an avalanche photodiode including a light receiving region, a cathode, and an anode. The first pixel includes a wiring layer electrically connected to the cathode and arranged in the sensor substrate such that the wiring layer is in a path of incident light that exits the light receiving region.

Abstract: An emitter array may comprise a plurality of vertical-emitting devices. The plurality of vertical-emitting devices may be in a two-dimensional pattern of vertical-emitting devices. The emitter array may further comprise a plurality of electrical contacts on a surface of the emitter array. Each of the plurality of electrical contacts may be co-located with and electrically connected to a corresponding vertical-emitting device of the plurality of vertical-emitting devices. The plurality of electrical contacts may provide mechanical support over the plurality of vertical-emitting devices. The plurality of electrical contacts may extend to approximately a same height. A subset of the plurality of vertical-emitting devices may be powered via a corresponding subset of the plurality of electrical contacts.

Abstract: An array imaging module includes at least two optical lenses and a molded photosensitive assembly, wherein the molded photosensitive assembly includes at least two photosensitive units, a circuit board that electrically couples to the photosensitive units, and a molded base having at least two optical windows. The molded base is integrally coupled at the circuit board at a peripheral portion thereof, wherein the photosensitive units are aligned with the optical windows respectively. The optical lenses are located along two photosensitive paths of the photosensitive units respectively, such that each of the optical windows forms a light channel through the corresponding photosensitive unit and the corresponding optical lens.

Abstract: The image sensing device includes a semiconductor substrate, an interconnection layer, a radiation-sensing region and an isolation structure. The semiconductor substrate has a front surface and a back surface. The interconnection layer is disposed over the front surface of the semiconductor substrate. The radiation-sensing region is disposed in the semiconductor substrate. The isolation structure is disposed on the back surface of the semiconductor substrate. The isolation structure includes a trench and an etch stop layer. The trench extends from the back surface of the semiconductor substrate. The etch stop layer is disposed along the trench. An etch selectivity of a silicon oxide film to the etch stop layer is greater than a predetermined value.

Abstract: A method for making a CMOS image sensor may include forming a first semiconductor chip including an array of image sensor pixels and readout circuitry electrically connected thereto, forming a second semiconductor chip including image processing circuitry electrically connected to the readout circuitry, and coupling the first semiconductor chip and the second semiconductor chip in a stack. The processing circuitry may include a plurality of transistors each including spaced apart source and drain regions, a superlattice channel extending between the source and drain regions, and a gate including a gate insulating layer on the superlattice channel and a gate electrode on the gate insulating layer.

Abstract: A method for making a CMOS image sensor may include forming a first semiconductor chip including an array of image sensor pixels and readout circuitry electrically connected thereto, forming a second semiconductor chip comprising image processing circuitry electrically connected to the readout circuitry, and coupling the first semiconductor chip and the second semiconductor chip together in a stack. The readout circuitry may include a plurality of transistors each including spaced apart source and drain regions, a superlattice channel extending between the source and drain regions, and a gate including a gate insulating layer on the superlattice channel and a gate electrode on the gate insulating layer.

Abstract: A detection apparatus according to an embodiment includes first detectors, a first electrode, second detectors and a second electrode. The first detectors detect a photon. The first electrode is electrically connected to each of the first detectors. The second detectors detect a photon. The second electrode is electrically connected to each of the second detectors. The number of first detectors is less than the number of second detectors.

Abstract: The invention relates to a photodetection device comprising a substrate and a diodes network, the substrate comprising an absorption layer and each diode comprising a collection region with a first type of doping in the absorption layer. The device comprises a conduction mesh under the surface of the substrate, comprising at least one conduction channel inserted between the collection regions of two adjacent diodes, the at least one conduction channel having a second doping type opposite the first type and a higher doping density than the absorption layer. The doping density of the at least one conduction channel is derived from metal diffusion in the absorption layer from a metal mesh present on the substrate surface. The absorption layer has the first doping type. The invention also relates to a method of making such a device.

Abstract: Some embodiments relate to a device array including a plurality of devices arranged in a semiconductor substrate. A protection ring circumscribes an outer perimeter of the device array. The protection ring includes a first ring neighboring the device array, a second ring circumscribing the first ring and meeting the first ring at a first p-n junction, and a third ring circumscribing the second ring and meeting the second ring at a second p-n junction. The first ring has a first width, the second ring has a second width, and the third ring has a third width. At least two of the first width, the second width, and the third width are different from one another.

Abstract: A method for making a CMOS image sensor may include forming an active pixel sensor array including pixels, each including a photodiode and read circuitry coupled to the photodiode and including transistors defining a 4T cell arrangement. At least one of the transistors may include a first semiconductor layer and a superlattice on the first semiconductor layer including a plurality of stacked groups of layers, with each group including a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The transistor(s) may also include a second semiconductor layer on the superlattice, spaced apart source and drain regions in the second semiconductor layer defining a channel therebetween, and a gate comprising a gate insulating layer on the second semiconductor layer and a gate electrode on the gate insulating layer.

Abstract: A beamformer for performing analog beamforming of ultrasound signals received from a plurality of transducer devices, the beamformer includes: first analog devices configured to output first ultrasound signals by delaying or transmitting the ultrasound signals based on a predetermined delay time; second analog devices configured to store first sub-ultrasound signals from among the first ultrasound signals, and to output the first sub-ultrasound signals depending on whether the first sub-ultrasound signals are repeatedly used; and a processor configured to control the delay time, and to perform the analog beamforming by summing the first ultrasound signals which correspond to the plurality of transducer devices and which are outputted depending on the delay time.

Abstract: A pixel element for an imaging sensor comprises a semiconductor substrate, a radiation-sensitive element configured to generate electric charges in response to incident radiation, a charge accumulation region provided in the semiconductor substrate configured to accumulate at least a portion of the electric charges, and an electrode arranged on the semiconductor substrate adjacent to the charge accumulation region. The electrode is electrically insulated from the semiconductor substrate such as to form an inversion region in the semiconductor substrate that connects to the charge accumulation region when a voltage is applied to said electrode.

Abstract: A solid-state image pickup apparatus includes a photoelectric conversion unit, a charge storage unit, and a floating diffusion unit, all disposed on a semiconductor substrate. The solid-state image pickup apparatus further includes a first gate electrode disposed on the semiconductor substrate and extending between the photoelectric conversion unit and charge storage unit, and a second gate electrode disposed on the semiconductor substrate and extending between the charge storage unit and the floating diffusion unit. The solid-state image pickup apparatus further includes a light shielding member including a first part and a second part, wherein the first part is disposed over the charge storage unit and at least over the first gate electrode or the second gate electrode, and the second part is disposed between the first gate electrode and the second gate electrode such that the second part extends from the first part toward a surface of the semiconductor substrate.

Abstract: A solid-state imaging device includes a plurality of pixels each of which includes a photoelectric conversion unit that generates charges by photoelectrically converting light, and a transistor that reads a pixel signal of a level corresponding to the charges generated in the photoelectric conversion unit. A phase difference pixel which is at least a part of the plurality of pixels is configured in such a manner that the photoelectric conversion unit is divided into a plurality of photoelectric conversion units and an insulated light shielding film is embedded in a region for separating the plurality of photoelectric conversion units, which are divided, from each other.

Abstract: According to one embodiment, a semiconductor device includes an interconnect layer, an electrical element, an optical element, and a resin portion. The resin portion includes a first partial region between the electrical element and the optical element. At least a portion of the optical element does not overlap the resin portion in a first direction. The first partial region has first and second resin portion surfaces. The second resin portion surface is opposite to the first resin portion surface and opposes the interconnect layer. The optical element has first and second optical element surfaces. The second optical element surface is opposite to the first optical element surface and opposes the interconnect layer. A distance along the first direction between the interconnect layer and the first resin portion surface is longer than a distance along the first direction between the interconnect layer and the first optical element surface.

Abstract: A solid-state image pickup apparatus includes a photoelectric conversion unit, a charge storage unit, and a floating diffusion unit, all disposed on a semiconductor substrate. The solid-state image pickup apparatus further includes a first gate electrode disposed on the semiconductor substrate and extending between the photoelectric conversion unit and charge storage unit, and a second gate electrode disposed on the semiconductor substrate and extending between the charge storage unit and the floating diffusion unit. The solid-state image pickup apparatus further includes a light shielding member including a first part and a second part, wherein the first part is disposed over the charge storage unit and at least over the first gate electrode or the second gate electrode, and the second part is disposed between the first gate electrode and the second gate electrode such that the second part extends from the first part toward a surface of the semiconductor substrate.

Abstract: The present invention relates to a display device and, particularly, to a display device using a semiconductor light-emitting device. The display device according to the present invention comprises a semiconductor light-emitting device, and the semiconductor light-emitting device comprises: a first conductive semiconductor layer; a second conductive semiconductor layer having a lateral surface, and overlapped with the first conductive semiconductor layer; a first conductive electrode electrically connected to the first conductive semiconductor layer; and a second conductive electrode electrically connected to the second conductive semiconductor layer, wherein the second conductive semiconductor layer has an inclined part inclined with respect to the lateral surface, and the second conductive electrode is formed so as to cover the inclined part.

Abstract: Aspects of the disclosure are directed to a metal only cell-based power grid (PG) architecture. In accordance with one aspect, the power gird (PG) architecture includes a cell building block structure with a N×M grid configuration including N cell building blocks arranged in a first direction and M cell building blocks arranged in a second direction, wherein the first direction and the second direction are orthogonal to one another; and a plurality of power grid (PG) cells, wherein each of the N cell building blocks and each of the M cell building blocks are occupied by a PG cell of the plurality of PG cells.

Abstract: 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.

Abstract: An image sensor includes a sensor portion and an ASIC portion bonded to the sensor portion. The sensor portion includes a first substrate having radiation-sensing pixels, a first interconnect structure, a first isolation layer, and a first dielectric layer. The ASIC portion includes a second substrate, a second isolation layer, and a second dielectric layer. The material compositions of the first and second isolation layers and the first and second dielectric layers are configured such that the first and second isolation layers may serve as barrier layers to prevent copper diffusion into oxide. The first and second isolation layers may also serve as etching-stop layers in the formation of the image sensor.

Abstract: The invention concerns an image sensor comprising: a depth pixel (PZ) having: a detection zone (PD); a first memory (mem1) electrically coupled to the detection zone by a first gate (310); a second memory (mem2) electrically coupled to the detection zone by a second gate (314); and a third memory (mem3) electrically coupled to the detection zone by a third gate (316), wherein the first, second and third memories are each formed by a doped region sandwiched between first and second parallel straight walls (404, 406), the first and second walls of each memory having a conductive core adapted to receive a biasing voltage; and a plurality of 2D image pixels (P1 to P8) positioned adjacent to the depth pixel, wherein the first, second and third memories extend to form at least partial isolation walls between corresponding adjacent pairs of the 2D image pixels.

Abstract: The present disclosure relates to a solid-state imaging device, a driving method for the same, and an electronic appliance, and an object is to provide a solid-state imaging device that can achieve the pixel miniaturization and the global shutter function with higher sensitivity and saturated charge amount. Another object is to provide an electronic appliance including the solid-state imaging device. In a solid-state imaging device 1 having the global shutter function, a first charge accumulation unit 18 and a second charge accumulation unit 25 are stacked in the depth direction of a substrate 12, and the transfer of the signal charges from the first charge accumulation unit 12 to the second charge accumulation unit 25 is conducted by a vertical first transfer transistor Tr1. Thus, the pixel miniaturization can be achieved.

Abstract: An image sensor arranged inside and on top of a semi-conductor substrate having a front surface and a rear surface, the sensor including a plurality of pixels, each including: a photosensitive area, a reading area, and a storage area extending between the photosensitive area and the reading area; a vertical insulated electrode including an opening of transfer between the photosensitive area and the storage area; and at least one insulation element among the following: a) a layer of an insulating material extending under the surface of the photosensitive area and of the storage area and having its front surface in contact with the rear surface of the electrode; and b) an insulating wall extending vertically in the opening, or under the opening.

Abstract: Structures and formation methods of an image sensor structure are provided. The image sensor structure is provided. The image sensor structure includes a substrate, a photodiode component in the substrate, and a grid structure over the substrate. The grid structure includes a bottom dielectric element over the substrate, a reflective element over the bottom dielectric element, and an upper dielectric element over the reflective element. The reflective element has a sidewall which is anti-corrosive in a basic condition and an acidic condition. The image sensor structure also includes a color filter element over the substrate and surrounded by the grid structure. The color filter element is aligned with the photodiode component.

Abstract: Image sensors include a color photo-sensing photoelectric conversion device, a first color filter and a second color filter disposed under the color photo-sensing photoelectric conversion device, a first photodiode and a second photodiode disposed under the first color filter and the second color filter, respectively, a first light guide member disposed between the first color filter and the first photodiode, and a second light guide member disposed between the second color filter and the second photodiode.

Abstract: A sensor chip formed from a plurality of sensor chips fabricated on a wafer, the wafer including a top surface, a bottom surface opposite the top surface and a thickness between the top and bottom surfaces, the sensor chip including an active area formed on the top surface, a first sacrificial edge including a first fiducial and a second fiducial, and a first score line formed in a first portion of the thickness on the top surface between the first sacrificial edge and the active area.

Abstract: A camera module is provided, including a lens driving mechanism, a lens unit, a circuit board, and an image sensor. The lens unit is disposed on the lens driving mechanism. The image sensor is disposed on the circuit board. The circuit board includes a metal member, an insulation layer, and a metal wire. The insulation layer is disposed between the metal member and the metal wire, and the metal wire is electrically connected to the image sensor. The lens driving module can drive the lens unit to move relative to the image sensor. The image sensor can catch the light through the lens unit.

Abstract: The present technology relates to a solid-state imaging device and an electronic apparatus that perform a stable overflow from a photodiode and prevent Qs from decreasing and color mixing from occurring. A solid-state imaging device according to an aspect of the present technology includes, at a light receiving surface side of a semiconductor substrate, a charge retention part that generates and retains a charge in response to incident light, an OFD into which the charge saturated at the charge retention part is discharged, and a potential barrier that becomes a barrier of the charge that flows from the charge retention part to the OFD, the OFD including a low concentration OFD and a high concentration OFD having different impurity concentrations of the same type, and the high concentration OFD and the potential barrier being formed at a distance. For example, the present technology is applicable to a CMOS image sensor.

Abstract: An image sensor configured to provide improved reliability may include a charge passivation layer that includes a multiple different elements, each element of the different elements being a metal element or a metalloid element. The different elements may include a first element of a first group of periodic table elements and a second element of a second, different group of periodic table elements. The charge passivation layer may include an amorphous crystal structure.

Abstract: Semiconductor devices, methods of manufacturing thereof, and image sensor devices are disclosed. In some embodiments, a semiconductor device comprises a semiconductor chip comprising an array region, a periphery region, and a through-via disposed therein. The semiconductor device comprises a guard structure disposed in the semiconductor chip between the array region and the through-via or between the through-via and a portion of the periphery region.

Abstract: An image sensor is described. The image sensor may include a substrate including a pixel area, a logic area, and a guard area disposed between the pixel area and the logic area. The guard area may substantially prevent transfer of heat generated in the logic area from reaching the pixel area.