Abstract: A semiconductor package is provided. The semiconductor package comprising a first redistribution structure comprising a first redistribution pattern; a first semiconductor chip on the first redistribution structure, the first semiconductor chip comprising a semiconductor substrate comprising a first surface and a second surface, a first back end of line (BEOL) structure on the first surface of the semiconductor substrate and comprising a first interconnect pattern, and a second BEOL structure on the second surface of the semiconductor substrate and comprising a second interconnect pattern; a molding layer covering a sidewall of the first semiconductor chip; a second redistribution structure on the first semiconductor chip and the molding layer and comprising a second redistribution pattern electrically connected to the second interconnect pattern.

Abstract: Provided are a package structure and a method of forming the same. The method includes providing a first package having a plurality of first dies and a plurality of second dies therein; performing a first sawing process to cut the first package into a plurality of second packages, wherein one of the plurality of second packages comprises three first dies and one second die; and performing a second sawing process to remove the second die of the one of the plurality of second packages, so that a cut second package is formed into a polygonal structure with the number of nodes greater than or equal to 5.

Abstract: In an embodiment a component includes a semiconductor chip, a connection member and a carrier, wherein the semiconductor chip is mechanically and electrically connected to the carrier via the connection member, wherein the connection member includes a contiguous metallic connecting layer and a plurality of metallic through-vias extending vertically through the connecting layer and being laterally spaced from the connecting layer by insulating regions, wherein the insulating regions are filled with a gaseous medium and are hermetically sealed, and wherein the gaseous medium contains an insulating gas having a higher breakdown field strength compared to nitrogen, or wherein a gas pressure is less than 1 mbar in the hermetically sealed insulating regions.

Abstract: A semiconductor device includes a first transistor having a first fin, wherein a base of the first fin is surrounded by a first dielectric material, the first fin having a first fin height measured from the top surface of the first dielectric material to a top surface of the first fin; and a second transistor having a second fin, wherein a base of the second fin is surrounded by a second dielectric material, the second fin having a second fin height measured from a top surface of the second dielectric material to a top surface of the second fin, wherein the first fin height is different from the second fin height.

Abstract: An integrated circuit (IC) device includes a substrate having opposite first and second sides, an active region over the first side of the substrate, a first transistor and a second transistor over the first side of the substrate, a first conductive pattern over the first side of the substrate, and a second conductive pattern under the second side of the substrate. The first conductive pattern electrically couples a first terminal of the first transistor to a second terminal of the second transistor. The second conductive pattern electrically couples the first terminal of the first transistor to the second terminal of the second transistor.

Abstract: In one embodiment, an asymmetric TVS device may include a semiconductor substrate, comprising an inner region, the inner region having a first polarity, and a first surface region, disposed on a first surface of the semiconductor substrate, the first surface region comprising a second polarity, opposite the first polarity. The asymmetric TVS device may also include a second surface region, comprising the second polarity, and disposed on a second surface of the semiconductor substrate, opposite the first surface, wherein the first surface region comprises a first dopant concentration, and wherein the second surface region comprises a second dopant concentration, greater than the first dopant concentration.

Abstract: Embodiments of the disclosure provide an integrated circuit (IC) structure, including a triple well structure within a semiconductor substrate. A base region is within a doped well of the triple well structure, a collector terminal is within the doped well and laterally separated from the base region by a first insulator and a first avalanche junction is defined between a first pair of oppositely-doped semiconductor regions within the collector terminal. An emitter terminal is within the third doped well of the triple well structure and laterally separated from the collector terminal by a second insulator. A second avalanche junction is defined between a second pair of oppositely-doped semiconductor regions of the emitter terminal.

Abstract: A method for fabricating a semiconductor device includes first providing a substrate having a high-voltage (HV) region, a medium-voltage (MV) region, and a low-voltage (LV) region, forming a HV device on the HV region, and forming a LV device on the LV region. Preferably, the HV device includes a first base on the substrate, a first gate dielectric layer on the first base, and a first gate electrode on the first gate dielectric layer. The LV device includes a fin-shaped structure on the substrate, and a second gate electrode on the fin-shaped structure, in which a top surface of the first gate dielectric layer is lower than a top surface of the fin-shaped structure.

Abstract: The semiconductor device according to the present application includes: a hole injection region including a hole injection layer and a semiconductor layer of a second conductivity type; a diode region including an anode layer of a second conductivity type and a cathode layer of a first conductivity type; a boundary portion semiconductor layer of a second conductivity type provided between the diode region and the hole injection region and provided on a first main surface side; a carrier injection suppression layer of a first conductivity type provided in a surface layer of the boundary portion semiconductor layer; and a semiconductor layer of a second conductivity type provided to protrude from the hole injection region on a second main surface side.

Abstract: A semiconductor device includes a semiconductor part, first and second electrodes, and a control electrode. The semiconductor part is provided between the first and second electrodes. The control electrode is provided in a trench of the semiconductor part between the semiconductor part and the second electrode. The semiconductor part includes first to third layers. The first layer of a first conductivity type extends between the first and second electrodes. The second layer of a second conductivity type is provided between the first layer and the second electrode. The second layer is connected to the second electrode. The third layer of the second conductivity type is provided between the second layer and the control electrode. The third layer includes a second-conductivity-type impurity with a higher concentration than a second-conductivity-type impurity of the second layer. The third layer contacts the second electrode, and is electrically connected to the second electrode.

Abstract: A reverse conducting insulated gate power semiconductor device is provided which comprises a plurality of active unit cells (40) and a pilot diode unit cell (50) comprising a second conductivity type anode region (51) in direct contact with a first main electrode (21) and extending from a first main side (11) to a first depth (d1). Each active unit cell (40) comprises a first conductivity type first source layer (41a) in direct contact with the first main electrode (21), a second conductivity type base layer (42) and a first gate electrode (47a), which is separated from the first source layer (41a) and the second conductivity type base layer (42) by a first gate insulating layer (46a) to form a first field effect transistor structure. A lateral size (w) of the anode region (51) in an orthogonal projection onto a vertical plane perpendicular to the first main side (11) is equal to or less than 1 ?m.

Abstract: A semiconductor arrangement and method of forming the same are described. A semiconductor arrangement includes a first gate structure on a first side of an active area and a second gate structure on a second side of the active area, where the first gate structure and the second gate structure share the active area. A method of forming the semiconductor arrangement includes forming a deep implant of the active area before forming the first gate structure, and then forming a shallow implant of the active area. Forming the deep implant prior to forming the first gate structure alleviates the need for an etching process that degrades the first gate structure. The first gate structure thus has a desired configuration and is able to be formed closer to other gate structures to enhance device density.

Abstract: Gate-all-around integrated circuit structures having adjacent island structures are described. For example, an integrated circuit structure includes a semiconductor island on a semiconductor substrate. A first vertical arrangement of horizontal nanowires is above a first fin protruding from the semiconductor substrate. A channel region of the first vertical arrangement of horizontal nanowires is electrically isolated from the fin. A second vertical arrangement of horizontal nanowires is above a second fin protruding from the semiconductor substrate. A channel region of the second vertical arrangement of horizontal nanowires is electrically isolated from the second fin. The semiconductor island is between the first vertical arrangement of horizontal nanowires and the second vertical arrangement of horizontal nanowires.

Abstract: A semiconductor device is provided. The semiconductor device includes a substrate including a first dummy region and a second dummy region spaced apart from the first dummy region; a device isolation layer filling a trench between the first dummy region and the second dummy region; a first dummy electrode provided on the first dummy region; a second dummy electrode provided on the second dummy region; a power line extending from the first dummy region to the second dummy region, the power line including an expanded portion provided on the device isolation layer, a width of the expanded portion being larger than a line width of a remaining portion of the power line; a power delivery network provided on a bottom surface of the substrate; and a through via extending through the substrate and the device isolation layer, and electrically connecting the power delivery network to the expanded portion. The through via and the expanded portion vertically overlap.

Abstract: The present disclosure relates to a semiconductor device and a method of forming the same, and the semiconductor device includes a substrate, a gate line and a stress layer. The substrate has a plurality of first fins protruded from the substrate. The gate line is disposed over the substrate, across the first fins, to further include a gate electrode and a gate dielectric layer, wherein the dielectric layer is disposed between the gate electrode layer and the first fins. The stress layer is disposed only on lateral surfaces of the first fins and on a top surface of the substrate, wherein a material of the stress layer is different from a material of the first fins.

Abstract: An integrated circuit die includes a FinFET transistor. The FinFET transistor includes an anti-punch through region below a channel region. Undesirable dopants are removed from the anti-punch through region during formation of the source and drain regions. When source and drain recesses are formed, a layer of dielectric material is deposited in the recesses. An annealing process is then performed. Undesirable dopants diffuse from the anti-punch through region into the layer of dielectric material during the annealing process. The layer of dielectric material is then removed. The source and drain regions are then formed by depositing semiconductor material in the recesses.

Abstract: Semiconductor structures and methods are provided. A method according to the present disclosure includes providing a workpiece that includes a plurality of active regions including channel regions and source/drain regions, and a plurality of dummy gate stacks intersecting the plurality of active regions at the channel regions, the plurality of dummy gate stacks including a device portion and a terminal end portion. The method further includes depositing a gate spacer layer over the workpiece, anisotropically etching the workpiece to recess the source/drain regions and to form a gate spacer from the gate spacer layer, forming a patterned photoresist layer over the workpiece to expose the device portion and the recessed source/drain regions while the terminal end portion is covered, and after the forming of the patterned photoresist layer, epitaxially forming source/drain features over the recessed source/drain regions.

Abstract: Techniques are disclosed for integrating semiconductor oxide materials as alternate channel materials for n-channel devices in integrated circuits. The semiconductor oxide material may have a wider band gap than the band gap of silicon. Additionally or alternatively, the high mobility, wide band gap semiconductor oxide material may have a higher electron mobility than silicon. The use of such semiconductor oxide materials can provide improved NMOS channel performance in the form of less off-state leakage and, in some instances, improved electron mobility as compared to silicon NMOS channels.

Abstract: Gate isolation techniques disclosed herein form gate isolation fins to isolate metal gates of multigate devices from one another before forming the multigate devices, and in particular, before forming the metal gates of the multigate devices. An exemplary device includes a first multigate device having first source/drain features and a first metal gate that surrounds a first channel layer and a second multigate device having second source/drain features and a second metal gate that surrounds a second channel layer. A gate isolation fin, which separates the first metal gate and the second metal gate, includes a dielectric feature having a first dielectric layer having a first dielectric constant (e.g., a low-k dielectric core) and a second dielectric layer (e.g., a high-k dielectric shell) surrounding the first dielectric layer. The second dielectric layer has a second dielectric constant that is greater than the first dielectric constant.

Abstract: A semiconductor device includes a first transistor, a division pattern, and a second transistor sequentially stacked on a substrate. The first transistor includes a first gate structure, a first source/drain layer at each of opposite sides of the first gate structure, and first semiconductor patterns spaced apart from each other in a vertical direction. Each of the first semiconductor patterns extends through the first gate structure and contacts the first source/drain layer. The division pattern includes an insulating material. The second transistor includes a second gate structure, a second source/drain layer at each of opposite sides of the second gate structure, and second semiconductor patterns spaced apart from each other in the vertical direction. Each of the second semiconductor patterns extends through the second gate structure and contacts the second source/drain layer. The first source/drain layer does not directly contact the second source/drain layer.

Abstract: An embodiment includes a first fin extending from a substrate. The device also includes a first gate stack over and along sidewalls of the first fin. The device also includes a first gate spacer disposed along a sidewall of the first gate stack. The device also includes a first epitaxial source/drain region in the first fin and adjacent the first gate spacer, an outer surface of the epitaxial first source/drain region having more than eight facets in a first plane, the first plane being orthogonal to a top surface of the substrate.

Abstract: A semiconductor device includes a substrate having a first power supply region, a second power supply region, and a cell region therein. The cell region extends between the first power supply region and the second power supply region. A first active region and a second active region are provided, which extend side-by-side within the cell region. A first power supply wiring is provided, which extends in the first direction within the first power supply region. A first source/drain contact is provided, which connects the first active region and the second active region. A second source/drain contact is provided, which connects the first active region and the first power supply wiring. The first source/drain contact includes a first recess portion disposed inside an intermediate region between the first active region and the second active region.

Abstract: A semiconductor device package is described that includes a power consuming device (such as an SOC device). The power consuming device may include one or more current consuming elements. A passive device may be coupled to the power consuming device. The passive device may include a plurality of passive elements formed on a semiconductor substrate. The passive elements may be arranged in an array of structures on the semiconductor substrate. The power consuming device and the passive device may be coupled using one or more terminals. The passive device and power consuming device coupling may be configured in such a way that the power consuming device determines functionally the way the passive device elements will be used.

Abstract: A vertical field effect transistor (VFET) cell implementing a VFET circuit over a plurality of gate grids includes: a 1st circuit including at least one VFET and provided over at least one gate grid; and a 2nd circuit including at least one VFET and provided over at least one gate grid formed on a left or right side of the 1st circuit, wherein a gate of the VFET of the 1st circuit is configured to share a gate signal or a source/drain signal of the VFET of the 2nd circuit, and the 1st circuit is an (X?1)-contacted poly pitch (CPP) circuit, which is (X?1) CPP wide, converted from an X-CPP circuit which is X CPP wide and performs a same logic function as the (X?1)-CPP circuit, X being an integer greater than 1.

Abstract: A semiconductor device includes a substrate having cell areas and power areas that are alternately arranged in a second direction. Gate structures extend in the second direction. The gate structures are spaced apart from each other in a first direction perpendicular to the second direction. Junction layers are arranged at both sides of each gate structure. The junction layers are arranged in the second direction such that each of the junction layer has a flat portion that is proximate to the power area. Cutting patterns are arranged in the power areas. The cutting patterns extend in the first direction such that each of the gate structures and each of the junction layers in neighboring cell areas are separated from each other by the cutting pattern.

Abstract: A semiconductor device is provided. The semiconductor device comprises a substrate including a first region, a second region, and a connecting region placed between the first region and the second region, a plurality of first multi-channel active patterns placed in the first region of the substrate, a plurality of second multi-channel active patterns placed in the second region of the substrate, a first connecting fin type pattern which is placed in the connecting region of the substrate and extends from the first region to the second region in a first direction, and a field insulating film which is placed on the substrate and covers an upper surface of the first connecting fin type pattern, wherein a width of the first connecting fin type pattern in a second direction decreases and then increases as it goes away from the first region, and the first direction is perpendicular to the second direction.

Abstract: A display panel and a display device are provided. By manufacturing a first via hole and a second via hole first, and then manufacturing a third via hole and a fourth via hole, the first via hole and the second via hole have been covered by a corresponding first drain electrode and first source electrode before performing hydrofluoric acid cleaning processes, and a first drain region and a first source region of a first oxide transistor are not affected by the hydrofluoric acid cleaning process, thereby allowing an oxide channel of the first oxide transistor to also be prevented from being affected.

Abstract: An embodiment is to include an inverted staggered (bottom gate structure) thin film transistor in which an oxide semiconductor film containing In, Ga, and Zn is used as a semiconductor layer and a buffer layer is provided between the semiconductor layer and a source and drain electrode layers. The buffer layer having higher carrier concentration than the semiconductor layer is provided intentionally between the source and drain electrode layers and the semiconductor layer, whereby an ohmic contact is formed.

Abstract: A touch array substrate and a manufacturing method thereof, wherein in the touch array substrate, an active layer, an insulating layer, a pixel electrode layer, a metal layer, a planarization layer, and a common electrode layer are sequentially disposed on the buffer layer. The active layer includes a first region corresponding to a source electrode and a second region corresponding to a drain electrode. The pixel electrode layer includes a plurality of base layers. The metal layer is correspondingly disposed on the base layers. The metal layer includes a touch signal line, a data line, and a gate electrode. The common electrode layer includes a touch electrode, the source electrode, and the drain electrode.

Abstract: An electronic device having a peripheral area and a non-peripheral area adjacent to the peripheral area is provided. The electronic device includes a flexible substrate, a first conductive layer disposed on the flexible substrate and disposed in the peripheral area and the non-peripheral area, an organic layer disposed in the non-peripheral area and on the first conductive layer, a second conductive layer disposed on the first conductive layer, and an organic structure disposed between the first conductive layer and the second conductive layer in the peripheral area. The organic layer and the organic structure are the same material layer.

Abstract: Provided are a display panel and a display device. In an embodiment, the display panel includes: a substrate; pixel circuit islands provided at a side of the substrate, one of the pixel circuit islands includes at least one pixel circuit; light-emitting elements provided at a side of the pixel circuit islands away from the substrate and respectively electrically connected to the pixel circuits of the pixel circuit islands; and light-blocking structures including at least one of a reflective structure or a light-absorbing structure. In an embodiment, the light-blocking structures include first light-blocking structures, each of which is provided on at least one sidewall of one pixel circuit island of the pixel circuit islands. In an embodiment, the first light-blocking structure prevents light out of the pixel circuit island from entering the pixel circuit island through the sidewall of the pixel circuit island.

Abstract: A display substrate, a display panel, and a display device are provided. The display substrate includes: a base substrate; a first semiconductor layer on the base substrate; and a second semiconductor layer on a side of the first semiconductor layer away from the base substrate. The display substrate further includes a plurality of thin film transistors on the base substrate, which at least include a first transistor, a second transistor and a third transistor. Each of the plurality of thin film transistors includes an active layer. The active layer of at least one of the first transistor and the second transistor is located in the second semiconductor layer and contains an oxide semiconductor material. The active layer of the third transistor is located in the first semiconductor layer and contains a polysilicon semiconductor material. At least one of the first transistor and the second transistor has a dual-gate structure.

Abstract: According to some embodiments of the present disclosure, a display device includes an active pattern including a metal oxide, a gate electrode overlapping the active pattern, a first capacitor electrode spaced apart from the active pattern and including a conductive oxide, and a second capacitor electrode on the first capacitor electrode.

Abstract: To provide a light-emitting device in which variation in luminance among pixels caused by variation in threshold voltage of transistors can be suppressed. The light-emitting device includes a transistor including a first gate and a second gate overlapping with each other with a semiconductor film therebetween, a first capacitor maintaining a potential difference between one of a source and a drain of the transistor and the first gate, a second capacitor maintaining a potential difference between one of the source and the drain of the transistor and the second gate, a switch controlling conduction between the second gate of the transistor and a wiring, and a light-emitting element to which drain current of the transistor is supplied.

Abstract: A display device and a method of manufacturing a display device are provided. The display device includes a first conductive layer on a substrate, a passivation layer disposed on the first conductive layer and exposing at least a part of the first conductive layer, a second conductive layer disposed on the passivation layer and covering an upper surface of the passivation layer, a via layer on the second conductive layer, a third conductive layer including a first electrode, a second electrode, and a connection pattern, and spaced apart from each other on the via layer, and a light emitting element having ends that are disposed on the first electrode and the second electrode, respectively. The connection pattern electrically connects the first conductive layer and the second conductive layer through a first contact hole penetrating the via layer.

Abstract: An image sensor including a semiconductor substrate having a first surface and a second surface; and a pixel isolation film extending from the first surface of the semiconductor substrate into the semiconductor substrate and defining active pixels in the semiconductor substrate, wherein the pixel isolation film includes a buried conductive layer including polysilicon containing a fining element at a first concentration; and an insulating liner between the buried conductive layer and the semiconductor substrate, and wherein the fining element includes oxygen, carbon, or fluorine.

Abstract: An imaging device with reduced power consumption is provided. The imaging device includes an imaging portion and an encoder. First image data obtained by the imaging portion is transmitted to the encoder. The encoder includes a first circuit that forms a neural network, and the first circuit conducts feature extraction by the neural network on a first image to generate second image data. Note that since the first circuit has a function of performing convolution processing using a weight filter, the encoder can perform computation with a convolutional neural network.

Abstract: An image sensor includes a substrate having a sensing area, a floating diffusion region arranged in the sensing area, a plurality of photodiodes arranged around the floating diffusion region in the sensing area, and an inter-pixel overflow (IPO) barrier in contact with each of the plurality of photodiodes, the IPO barrier overlapping the floating diffusion region in a vertical direction at a position vertically spaced apart from the floating diffusion region within the sensing area.

Abstract: A unit pixel arranged along with a display pixel in each pixel of a display panel is provided. The unit pixel may include a thin-film transistor (TFT) photodetector including an active layer formed of amorphous silicon or polycrystalline silicon on an amorphous transparent substrate, and at least one transistor electrically coupled to the TFT photodetector and configured to generate a voltage output from photocurrent generated from the active layer.

Abstract: A photoelectric conversion device includes a semiconductor substrate, a photoelectric conversion unit, an amplification transistor, and an insulating isolation portion. The photoelectric conversion unit is disposed inside the semiconductor substrate. The amplification transistor is configured to output a signal from the photoelectric conversion unit. The insulating isolation portion, disposed between the photoelectric conversion unit and the amplification transistor to surround the amplification transistor in a plan view, is configured to penetrate through the semiconductor substrate. A first well in which the amplification transistor is disposed is connected to a source or a drain of the amplification transistor.

Abstract: An image sensing device is provided to include a plurality of unit pixel regions arranged in a first direction and a second direction, a first device isolation region structured to isolate the plurality of unit pixel regions from each other, a plurality of photoelectric conversion regions in the substrate to form a plurality of imaging pixels structured to generate photocharges, a plurality of second device isolation regions configured to define active regions of the plurality of imaging pixels, a plurality of floating diffusion regions formed in a first active region to store the photocharges, and a plurality of transfer gates structured to transmit the photocharges. The floating diffusion region is located contiguous to the transfer gate in the first direction and the second direction and is structured to surround a plurality of side surfaces of a corresponding transfer gate.

Abstract: Provided are a camera module, a molding photosensitive assembly and manufacturing method thereof, and an electronic device. The molding photosensitive assembly comprises a molding portion, at least one photosensitive chip and at least one circuit board, wherein the photosensitive chip is provided on the circuit board, the molding portion comprises a molding portion main body, the molding portion main body is made of a transparent material, and the molding portion main body, the photosensitive chip and the circuit board form an integral structure by means of a molding technique, so as to facilitate production.

Abstract: According to an aspect, an image sensor package includes a substrate, an image sensor die coupled to the substrate, and a transparent member including a first surface and a second surface, where the second surface of the transparent member is coupled to the image sensor die via one or more dam members such that an empty space exists between an active area of the image sensor die and the second surface of the transparent member. The image sensor package includes a light blocking member coupled to or defined by the transparent member.

Abstract: There is provided a solid-state imaging device including a substrate having a surface over which a plurality of photodiodes are formed, and a protection film that is transparent, has a water-proofing property, and includes a side wall part vertical to the surface of the substrate and a ceiling part covering a region surrounded by the side wall part, the side wall part and the ceiling part surrounding a region where the plurality of photodiodes are arranged over the substrate.

Abstract: Provided is a solid-state imaging device capable of enhancing pixel sensitivity and preventing color mixture. A solid-state imaging device includes: a plurality of microlenses that condenses incident light; a plurality of color filters that transmits light of a specific wavelength included in the condensed incident light; a plurality of photoelectric conversion parts on which light having a specific wavelength transmitted through the color filter is incident; and a plurality of waveguide wall parts arranged between the color filters and surrounding the color filter. Then, each of the plurality of waveguide wall parts is formed in a position subjected to pupil correction.

Abstract: An image sensor package includes a substrate and an image sensor on the substrate. An adhesive film is on the image sensor. A transparent cover is on the adhesive film. The transparent cover includes a top surface, a first side surface and a second side surface disposed on the first side surface. The second side surface is inclined with respect to an extending direction of a bottom surface of the transparent cover. A mold layer covers an upper surface of the substrate, a side surface of the image sensor, a side surface of the adhesive film, the first side surface of the transparent cover and a partial portion of the second side surface of the transparent cover. A top surface of the mold layer is higher than a lower end of the second side surface and lower than the top surface of the transparent cover.

Abstract: A method of manufacturing a solid-state image sensor comprising a pixel part including a photoelectric conversion element and a MOS transistor, comprising steps of forming a first insulating film made of a nitrogen-containing silicon compound on the photoelectric conversion element and the MOS transistor, forming an opening in at least a portion of the first insulating film, which is positioned above a channel of the MOS transistor, forming a second insulating film on the first insulating film, forming a contact hole extending through the second insulating film and the first insulating film, and forming, in the contact hole, a contact plug to be connected to the MOS transistor.

Abstract: Provided is an image sensor including a sensor chip including a first substrate and a first interconnection layer, a logic chip including a second substrate and a second interconnection layer, a through-hole penetrating a portion of the second interconnection layer, the first substrate, and the first interconnection layer, and a first connection structure disposed on an inner surface of the through-hole and extending from the first substrate toward the second interconnection layer, wherein the first interconnection layer includes a first interlayer insulating layer and a first interconnection pattern, the second interconnection layer includes a second interlayer insulating layer and a second interconnection pattern, the through-hole includes first and second trenches respectively extending from the through-hole toward the second interconnection layer, bottom surfaces of the first and second trenches contact the second interconnection pattern, and a bottom surface of the through-hole contacts the first interco

Abstract: A solid-state image pickup device capable of suppressing the generation of dark current and/or leakage current is provided. The solid-state image pickup device has a first substrate provided with a photoelectric converter on its primary face, a first wiring structure having a first bonding portion which contains a conductive material, a second substrate provided with a part of a peripheral circuit on its primary face, and a second wiring structure having a second bonding portion which contains a conductive material. In addition, the first bonding portion and the second bonding portion are bonded so that the first substrate, the first wiring structure, the second wiring structure, and the second substrate are disposed in this order. Furthermore, the conductive material of the first bonding portion and the conductive material of the second bonding portion are surrounded with diffusion preventing films.

Abstract: A solid-state imaging device includes a pixel having a photoelectric conversion element which generates a charge in response to incident light, a first transfer gate which transfers the charge from the photoelectric conversion element to a charge holding section, and a second transfer gate which transfers the charge from the charge holding section to a floating diffusion. The first transfer gate includes a trench gate structure having at least two trench gate sections embedded in a depth direction of a semiconductor substrate, and the charge holding section includes a semiconductor region positioned between adjacent trench gate sections.