A p anode layer is formed on one main surface of an n.sup. drift layer. N.sup.+ cathode layer having an impurity concentration more than that of the n.sup. drift layer is formed on the other main surface. An anode electrode is formed on the surface of the p anode layer. A cathode electrode is formed on the surface of the n.sup.+ cathode layer. N-type broad buffer region having a net doping concentration more than the bulk impurity concentration of a wafer and less than the n.sup.+ cathode layer and p anode layer is formed in the n.sup. drift layer. Resistivity .sub.0 of the n.sup. drift layer satisfies 0.12V.sub.0.sub.00.25V.sub.0 with respect to rated voltage V.sub.0. Total amount of net doping concentration of the broad buffer region is equal to or more than 4.810.sup.11 atoms/cm.sup.2 and equal to or less than 1.010.sup.12 atoms/cm.sup.2.

A method of manufacturing a semiconductor structure includes: forming a light-absorption layer in a substrate; forming a first doped region of a first conductivity type and a second doped region of a second conductivity type in the light-absorption layer adjacent to the first doped region; depositing a first patterned mask layer over the light-absorption layer, wherein the first patterned mask layer includes an opening exposing the second doped region and covers the first doped region; forming a first silicide layer in the opening on the second doped region; depositing a barrier layer over the first doped region; and annealing the barrier layer to form a second silicide layer on the first doped region.

An optical apparatus including a semiconductor substrate; a first light absorption region supported by the semiconductor substrate, the first light absorption region including germanium and configured to absorb photons and to generate photo-carriers from the absorbed photons; a first layer supported by at least a portion of the semiconductor substrate and the first light absorption region, the first layer being different from the first light absorption region; one or more first switches controlled by a first control signal, the one or more first switches configured to collect at least a portion of the photo-carriers based on the first control signal; and one or more second switches controlled by a second control signal, the one or more second switches configured to collect at least a portion of the photo-carriers based on the second control signal, wherein the second control signal is different from the first control signal.

An optical apparatus including a semiconductor substrate; a first light absorption region supported by the semiconductor substrate, the first light absorption region configured to absorb photons and to generate photo-carriers from the absorbed photons; one or more first switches controlled by a first control signal, the one or more first switches configured to collect at least a portion of the photo-carriers based on the first control signal; one or more second switches controlled by a second control signal, the one or more second switches configured to collect at least a portion of the photo-carriers based on the second control signal; and a counter-doped region formed in a first portion of the first light absorption region, the counter-doped region including a first dopant and having a first net carrier concentration lower than a second net carrier concentration of a second portion of the first light absorption region.

A thyristor includes a first conductivity type semiconductor layer, a first conductivity type carrier injection layer on the semiconductor layer, a second conductivity type drift layer on the carrier injection layer, a first conductivity type base layer on the drift layer, and a second conductivity type anode region on the base layer. The thickness and doping concentration of the carrier injection layer are selected to reduce minority carrier injection by the carrier injection layer in response to an increase in operating temperature of the thyristor. A cross-over current density at which the thyristor shifts from a negative temperature coefficient of forward voltage to a positive temperature coefficient of forward voltage is thereby reduced.

A method of manufacturing a semiconductor structure includes: forming a light-absorption layer in a substrate, wherein the light-absorption layer includes an upper surface above an upper surface of the substrate; forming a first doped region and a second doped region in the light-absorption layer adjacent to the first doped region; depositing a first patterned mask layer over the light-absorption layer, wherein the first patterned mask layer includes an opening exposing the second doped region and covers the first doped region; forming a first silicide layer in the opening on the second doped region; and forming a second silicide layer on the first doped region.

Provided is an electrostatic protection circuit that has little leakage current under normal operation and allows a trigger voltage to be set comparatively freely, without requiring a special process step. This electrostatic protection circuit is provided with a series circuit including a transistor, a predetermined number of diodes and an impedance element that are connected in series between the first node and the second node, and a discharge circuit configured to send current from the first node to the second node following an increase in a potential difference that occurs between both ends of the impedance element, when the first node reaches a higher potential than the second node and current flows through the series circuit. The predetermined number of diodes are connected between the source and the back gate of the transistor.

Semiconductor devices includes a thin epitaxial layer (nanotube) formed on sidewalls of mesas formed in a semiconductor layer. In one embodiment, a semiconductor device includes a first semiconductor layer, a second semiconductor layer formed thereon and of the opposite conductivity type, and a first epitaxial layer formed on mesas of the second semiconductor layer. An electric field along a length of the first epitaxial layer is uniformly distributed.

A semiconductor device includes transistor cells formed inside a semiconductor body. First and second semiconductor well regions have second conductivity type dopants and are arranged external of the transistor cells. The first semiconductor well region is arranged between two transistor cells and the second semiconductor well region is electrically connected with a load contact. A separation region has first conductivity type dopants and extends from a surface of the semiconductor body along the vertical direction and is arranged between and in contact with each of the first and second semiconductor well regions. The first semiconductor well region extends at least as deep as each of body regions of two transistor cells. A transition in a first lateral direction between the separation and first semiconductor well regions extends continuously from the surface to a point in the semiconductor body at least as deep as each body region of two transistor cells.

The invention relates to a detector element which has the following features: an epitaxial semiconductor layer sequence including at least two active layers which are designed to absorb electromagnetic radiation with a wavelength L1, wherein the epitaxial semiconductor layer sequence has a first main surface and a second main surface lying opposite the first main surface, each surface being designed to couple in and couple out electromagnetic radiation, and at least three electric connection contacts which are designed to electrically contact the active layers, an electric connection contact being arranged between two active layers. The invention additionally relates to a lidar module and to a method for operating a lidar module.