A semiconductor device, a manufacturing method therefor, and an electronic apparatus that reduces a parasitic capacitance generated between an internal electrode and a board silicon to suppress waveform distortion and signal delay of high-frequency signals, thereby enabling a high-speed operation. A configuration to include: a board silicon; a silicon oxide film stacked on the board silicon; an inter-wiring-layer film having an internal electrode stacked on the silicon oxide film; a through-hole forming a stepped hole with a larger-diameter hole extending from the board silicon to the silicon oxide film and a smaller-diameter hole extending from the silicon oxide film to the internal electrode; an interlayer dielectric film stacked on a circumferential side surface of the larger-diameter hole and the board silicon; and a redistribution layer on an inner peripheral surface of the through-hole and the interlayer dielectric film and connected to the internal electrode.

A device for producing electrical current. In one embodiment, the device comprises a stack of epitaxial layers (from a bottom surface): a p-doped semiconductor reflector layer, a p-doped semiconductor emitter layer, an n-doped semiconductor base layer, and an n-doped semiconductor window layer. A radioisotope source, disposed above or in contact with an uppermost layer of the stack, produces radioisotope decay particles or gamma rays that impinge the stack. The electrical current is produced between the first and second conductive regions by action of the radioisotope decay particles or the gamma rays on the emitter and base layers.

A molding is formed by laminating an aggregate of SiC and a paste containing Si and C powders on an epitaxial layer of SiC formed on a support substrate of SiC to form an intermediate sintered body in which polycrystalline SiC is produced from the Si and C powders by reaction sintering, free Si is carbonized to SiC to form a sintered body layer, and the support substrate is removed from the epitaxial layer to form a semiconductor substrate in which the epitaxial layer and the sintered body layer are laminated.

In an embodiment, an optoelectronic component includes a structured region including a semiconductor body having a first semiconductor region and a second semiconductor region, which have different conductivities, a first main surface and a second main surface and at least one first delimiting surface and at least one second delimiting surface delimiting a recess, a protective layer, which is arranged on the at least one first delimiting surface and covers a junction between the first semiconductor region and the second semiconductor region in the recess, wherein the first main surface is not covered by the protective layer and the protective layer does not adjoin any further protective layer on a side facing the junction and on a side facing away from the junction, and wherein the protective layer is retracted from the first delimiting surface and the second delimiting surface or wherein the protective layer has an L-shape in cross-section.

An optical sensor includes a substrate, a photoelectric element disposed on the substrate and that includes a first electrode, an intermediate layer disposed on the first electrode, and a second electrode disposed on the intermediate layer, a barrier layer disposed on the second electrode, an insulating layer that covers the photoelectric element and the barrier layer, and a bias electrode disposed on the insulating layer and electrically connected to the second electrode. The barrier layer is spaced apart from the first electrode.

The photodetector is formed in a silicon carbide body formed by a first epitaxial layer of an N type and a second epitaxial layer of a P type. The first and second epitaxial layers are arranged on each other and form a body surface including a projecting portion, a sloped lateral portion, and an edge portion. An insulating edge region extends over the sloped lateral portion and the edge portion. An anode region is formed by the second epitaxial layer and is delimited by the projecting portion and by the sloped lateral portion. The first epitaxial layer forms a cathode region underneath the anode region. A buried region of an N type, with a higher doping level than the first epitaxial layer, extends between the anode and cathode regions, underneath the projecting portion, at a distance from the sloped lateral portion as well as from the edge region.

A guard ring structure and a component structure are provided. The guard ring structure includes a first attached guard ring and a second attached guard ring. The first attached guard ring is disposed at a periphery of an active region. The second attached guard ring is disposed at a periphery of the first attached guard ring. The first attached guard ring and the second attached guard ring are each an attached guard ring, and form a stepped structure. The guard ring structure is a stepped diffusion structure for an avalanche photodiode.

A method of manufacturing a semiconductor device is provided, including: forming a first conductive type lightly doped region in the epitaxial layer; forming a first conductive type heavily doped region and a second conductive type heavily doped region in the epitaxial layer on the first conductive type lightly doped region, in which the neighboring first conductive type heavily doped regions are spaced apart by the second conductive type heavily doped region; disposing the mask on the second conductive type heavily doped region; disposing a spacer on a sidewall of the mask; doping a first conductive type dopant in the first conductive type lightly doped region to form an anti-breakdown region; removing the mask and forming a trench extending into the second conductive type heavily doped region, first conductive type lightly doped region and the epitaxial layer; and removing the spacer.

A contact to a semiconductor heterostructure is described. In one embodiment, there is an n-type semiconductor contact layer. A light generating structure formed over the n-type semiconductor contact layer has a set of quantum wells and barriers configured to emit or absorb target radiation. An ultraviolet transparent semiconductor layer having a non-uniform thickness is formed over the light generating structure. A p-type contact semiconductor layer having a non-uniform thickness is formed over the ultraviolet transparent semiconductor layer.

BSI image sensors and methods. In an embodiment, a substrate is provided having a sensor array and a periphery region and having a front side and a back side surface; a bottom anti-reflective coating (BARC) is formed over the back side to a first thickness, over the sensor array region and the periphery region; forming a first dielectric layer over the BARC; a metal shield is formed; selectively removing the metal shield from over the sensor array region; selectively removing the first dielectric layer from over the sensor array region, wherein a portion of the first thickness of the BARC is also removed and a remainder of the first thickness of the BARC remains during the process of selectively removing the first dielectric layer; forming a second dielectric layer over the remainder of the BARC and over the metal shield; and forming a passivation layer over the second dielectric layer.