Abstract: The lateral single-photon avalanche diode comprises a semiconductor body comprising a semiconductor material of a first type of electric conductivity, a trench in the semiconductor body, and anode and cathode terminals. A junction region of the first type of electric conductivity is located near the sidewall of the trench, and the electric conductivity is higher in the junction region than at a farther distance from the sidewall. A semiconductor layer of an opposite second type of electric conductivity is arranged at the sidewall of the trench adjacent to the junction region. The anode and cathode terminals are electrically connected with the semiconductor layer and with the junction region, respectively. The junction region may be formed by a sidewall implantation.

Abstract: The semiconductor device comprises a substrate (1) of semiconductor material, a dielectric layer (2) above the substrate, a waveguide (3) arranged in the dielectric layer, and a mirror region (4) arranged on a surface of a mirror support (5) integrated on the substrate. A mirror is thus formed facing the waveguide. The surface of the mirror support and hence the mirror are inclined with respect to the waveguide.

Abstract: The semiconductor device comprises a substrate (1) of semiconductor material, a dielectric layer (2) above the substrate, a waveguide (3) arranged in the dielectric layer, and a mirror region (4) arranged on a surface of a mirror support (5) integrated on the substrate. A mirror is thus formed facing the waveguide. The surface of the mirror support and hence the mirror are inclined with respect to the waveguide.

Abstract: The method comprises the steps of providing a semiconductor body or substrate (1) with a recess or trench (2) in a main surface (10), applying a mask (3) on the main surface, the mask covering the recess or trench, so that the walls and bottom of the recess or trench and the mask together enclose a cavity (4), which is filled with a gas, and forming at least one opening (5) in the mask at a distance from the recess or trench, the distance (6) being adapted to allow the gas to escape from the cavity via the opening when the gas pressure exceeds an external pressure.

Abstract: A cutout (11), which penetrates the semiconductor body, is present in the semiconductor body (1). A conductor layer (6), which is electrically conductively connected to a metal plane (3) on or over the semiconductor body, screens the semiconductor body electrically from the cutout. The conductor layer can be metal, optionally with a barrier layer (6a), or a doped region of the semiconductor body.

Abstract: The lateral single-photon avalanche diode comprises a semiconductor body comprising a semiconductor material of a first type of electric conductivity, a trench in the semiconductor body, and anode and cathode terminals. A junction region of the first type of electric conductivity is located near the sidewall of the trench, and the electric conductivity is higher in the junction region than at a farther distance from the sidewall. A semiconductor layer of an opposite second type of electric conductivity is arranged at the sidewall of the trench adjacent to the junction region. The anode and cathode terminals are electrically connected with the semiconductor layer and with the junction region, respectively. The junction region may be formed by a sidewall implantation.

Abstract: The method comprises the steps of providing a semiconductor body or substrate (1) with a recess or trench (2) in a main surface (10), applying a mask (3) on the main surface, the mask covering the recess or trench, so that the walls and bottom of the recess or trench and the mask together enclose a cavity (4), which is filled with a gas, and forming at least one opening (5) in the mask at a distance from the recess or trench, the distance (6) being adapted to allow the gas to escape from the cavity via the opening when the gas pressure exceeds an external pressure.

Abstract: A cutout (11), which penetrates the semiconductor body, is present in the semiconductor body (1). A conductor layer (6), which is electrically conductively connected to a metal plane (3) on or over the semiconductor body, screens the semiconductor body electrically from the cutout. The conductor layer can be metal, optionally with a barrier layer (6a), or a doped region of the semiconductor body.

Abstract: A silicon substrate includes plural partial areas defined on the silicon substrate such that adjacent partial areas are orientated in different directions. The plural partial areas define an insulating layer that extends from a surface of the silicon subtrate into the silicon substrate. Each of the plural partial areas includes first regions that contain silicon dioxide formed by oxidation of silicon in the silicon substrate, and second regions that contain silicon dioxide deposited onto the silicon substrate. The first regions and the second regions are oriented in a substantially same direction and are arranged side-by-side and alternately such that two first regions do not border and two second regions do not border.