In a plan view of a semiconductor substrate, the semiconductor substrate includes a pillar exposing area in which the pillar region is exposed on the front surface of the semiconductor substrate, a pillar contacting area in which the pillar region is in contact with a deeper side of the anode contact region, and an anode contacting area in which the anode region is in contact with the deeper side of the anode contact region. In a direction along which the pillar contacting area and the anode contacting area are aligned, a width of the pillar contacting area is smaller than a width of the anode contacting area.

The invention provides a semiconductor device, including a buried oxide layer disposed on a substrate. A semiconductor layer is disposed on the buried oxide layer. A first well is disposed in the semiconductor layer. A second well and a third well are disposed to opposite sides of the first well and separated from the first well. An isolation feature covers the first well and the third well. A poly field plate is disposed on the isolation feature and over the semiconductor layer between the first well and the third well. A first anode doped region is disposed on the second well. A second anode doped region and a third anode doped region are disposed on the second well. The second anode doped region is positioned directly on the third anode doped region. A first cathode doped region is coupled to the third well.

A transistor includes first and second load terminals and a semiconductor body coupled to both terminals. The semiconductor body includes: a drift region having dopants of a first conductivity type; a transistor section for conducting a forward load current and having a control head coupling the first load terminal to a first side of the drift region; and a diode section for conducting a reverse load current. A diode port couples the second load terminal to a second side of the drift region and includes: a first emitter electrically connected to the second load terminal and having dopants of the first conductivity type for injecting majority charge carriers into the drift region; and a second emitter having dopants of a second conductivity type for injecting minority charge carriers into the drift region. A pn-junction transition between the first and second emitters has a breakdown voltage of less than 10 V.

A method of manufacturing a semiconductor device includes forming a frame trench extending from a first surface into a base substrate, forming, in the frame trench, an edge termination structure comprising a glass structure, forming a conductive layer on the semiconductor substrate and the edge termination structure, and removing a portion of the conductive layer above the edge termination structure. A remnant portion of the conductive layer forms a conductive structure that covers a portion of the edge termination structure directly adjoining a sidewall of the frame trench.

The present disclosure relates to a Zener diode including a Zener diode junction formed in a semiconductor substrate along a plane parallel to the surface of the substrate, and positioned between a an anode region having a first conductivity type and a cathode region having a second conductivity type, the cathode region extending from the surface of the substrate. A first conducting region is configured to generate a first electric field perpendicular to the plane of the Zener diode junction upon application of a first voltage to the first conducting region, and a second conducting region is configured to generate a second electric field along the plane of the Zener diode junction upon application of a second voltage to the second conducting region.

A power semiconductor device includes: a substrate; an anode electrode and a cathode electrode disposed on the substrate; a well region disposed inside the substrate in a lower portion of the anode electrode, and having p-type conductivity; an NISO region disposed in a lower portion of the well region inside the substrate, and having a first n-type impurity concentration; and an n-type buried layer disposed in a lower portion of the NISO region, and having a second impurity concentration greater than the first n-type impurity concentration, inside the substrate.

A junction barrier Schottky rectifier with first and second drift layer sections, wherein a peak net doping concentration of the first section is at least two times lower than a minimum net doping concentration of the second section. For each emitter region the first section includes a layer which is in contact with the respective emitter region to form a pn-junction between the first section and the respective emitter region, wherein the thickness of this layer in a direction perpendicular to the interface between the first section and the respective emitter region is at least 0.1 m. The JBS rectifier has a transition from unipolar to bipolar conduction mode at a lower forward bias due to lowering of electrostatic forces otherwise impairing the transport of electrons toward the emitter regions under forward bias conditions, and with reduced snap-back phenomenon.

The present invention is directed to a chip diode with a Zener voltage Vz of 4.0 V to 5.5 V, including a semiconductor substrate having a resistivity of 3 m.Math.cm to 5 m.Math.cm and a diffusion layer formed on a surface of the semiconductor substrate and defining a diode junction region with the semiconductor substrate therebetween, in which the diffusion layer has a depth of 0.01 m to 0.2 m from the surface of the semiconductor substrate.

A diode having excellent switching characteristics is provided. A diode includes a silicon carbide substrate, a stop layer, a drift layer, a guard ring, a Schottky electrode, an ohmic electrode, and a surface protecting film. At a measurement temperature of 25 C., a product RQ of a forward ON resistance R of the diode and response charges Q of the diode satisfies relation of RQ0.24V.sub.blocking.sup.2. The ON resistance R is found from forward current-voltage characteristics of the diode. A reverse blocking voltage V.sub.blocking is defined as a reverse voltage which produces breakdown of the diode. The response charges Q are found by integrating a capacitance (C) obtained in reverse capacitance-voltage characteristics of the diode in a range from 0 V to V.sub.blocking.

The invention provides a semiconductor device. The semiconductor device includes a buried oxide layer disposed on a substrate. A semiconductor layer having a first conduction type is disposed on the buried oxide layer. A first well doped region having a second conduction type is disposed in the semiconductor layer. A cathode doped region having the second conduction type is disposed in the first well doped region. A first anode doped region having the first conduction type is disposed in the first well doped region, separated from the cathode doped region. A first distance from a bottom boundary of the first anode doped region to a top surface of the semiconductor layer is greater than a second distance from the bottom boundary to an interface between the semiconductor layer and the buried oxide layer.