Abstract: In an embodiment, a semiconductor device includes: a main bi-directional switch formed on a semiconductor substrate and including first and second gates, a first source electrically connected to a first voltage terminal, a second source electrically connected to a second voltage terminal, and a common drain; and a substrate control circuit. The substrate control circuit includes: a first diode and a second diode; a discharge circuit including a first transistor and a second transistor connected in a common source configuration to the semiconductor substrate; and a gate potential control circuit including a third diode and a fourth diode. The first diode has a forward voltage Vf1 and the third diode has a forward voltage Vf3, where Vf1?1.1Vf4 or Vf1?1.2Vf4 or Vf1?1.5Vf4 or Vf1?2Vf4.

Abstract: A semiconductor device includes type IV semiconductor base substrate, first and second device areas that are electrically isolated from one another, a first region of type III-V semiconductor material formed over the first device area, a second region of type III-V semiconductor material formed over the second device area, the second region of type III-V semiconductor material being laterally electrically insulated from the first region of type III-V semiconductor material, a first high-electron mobility transistor integrally formed in the first region, and a second high-electron mobility transistor integrally formed in the second region. The first and second high-electron mobility transistors are connected in series. A source terminal of the first high-electron mobility transistor is electrically connected to the first device area. The first device area is electrically isolated from a subjacent intrinsically doped region of the base substrate by a first two-way voltage blocking device.

Abstract: A semiconductor die includes a barrier layer of type III-V semiconductor material, a channel layer of type III-V semiconductor material disposed below the barrier layer, the channel layer forming a heterojunction with the barrier layer such that a two-dimensional charge carrier gas is disposed in the channel layer near the heterojunction, and a capacitor monolithically formed in the semiconductor die, wherein a dielectric medium of the capacitor includes a first section of the barrier layer.

Abstract: A semiconductor device includes a main bi-directional switch formed on a semiconductor substrate and having first and second gates, a first source electrically connected to a first voltage terminal, a second source electrically connected to a second voltage terminal, and a common drain. The semiconductor device further includes a discharge circuit having a plurality of individual transistors or an auxiliary bi-directional switch monolithically integrated with the main bi-directional switch and connected in a common source configuration to the semiconductor substrate. The plurality of individual transistors or the auxiliary bi-directional switch includes a first drain connected to the first source of the main bi-directional switch, a second drain connected to the second source of the main bi-directional switch, and first and second gates each decoupled from gate drive circuitry so that the first and the second gates are controlled at least passively and based on a state of the main bi-directional switch.

Abstract: A semiconductor device includes a type IV semiconductor base substrate, a first type III-V semiconductor layer formed on a first surface of the base substrate, and a second type III-V semiconductor layer with a different bandgap as the first type III-V being formed on the first type III-V semiconductor layer. The semiconductor device further includes first and second electrically conductive device terminals each being formed on the second type III-V semiconductor layer and each being in ohmic contact with the two-dimensional charge carrier gas. The base substrate includes a dielectric layer formed directly on a lower region of type IV semiconductor material, and a highly-doped layer of type IV semiconductor material formed directly on the dielectric layer.

Abstract: In an embodiment, a switching circuit is provided that includes a Group III nitride-based semiconductor body including a first monolithically integrated Group III nitride-based transistor device and a second monolithically integrated Group III nitride based transistor device that are coupled to form a half-bridge circuit and are arranged on a common foreign substrate having a common doping level. The switching circuit is configured to operate the half-bridge circuit at a voltage of at least 300V.

Abstract: A Group III nitride transistor cell is provided that includes a Group III nitride-based body, a source finger, a gate finger, and a drain finger extending substantially parallel to one another and positioned on the Group III nitride-based body, the gate finger being arranged laterally between the source finger and the drain finger and including a p-type Group III nitride finger arranged on the Group III nitride body and a gate metal finger arranged on the p-type Group III nitride finger, and a protection diode. The protection diode is integrated into the Group III nitride transistor cell and operable to conduct current in a reverse direction when the Group III nitride transistor cell is switched off. The protection diode is electrically coupled between the source and drain fingers and is positioned on the Group III nitride body laterally between and spaced apart from the gate finger and the drain finger.

Abstract: A semiconductor device includes a type IV semiconductor base substrate, a first type III-V semiconductor layer formed on a first surface of the base substrate, and a second type III-V semiconductor layer with a different bandgap as the first type III-V being formed on the first type III-V semiconductor layer. The semiconductor device further includes first and second electrically conductive device terminals each being formed on the second type III-V semiconductor layer and each being in ohmic contact with the two-dimensional charge carrier gas. The base substrate includes a first highly doped island that is disposed directly beneath the second device terminal and extends to the first surface of the base substrate. The first highly-doped island is laterally disposed between portions of semiconductor material having a lower net doping concentration than the first highly-doped island.

Abstract: The invention relates to a lateral field effect transistor, in particular a HEMT having a heterostructure, in a III/V semiconductor system with a p-type semiconductor being arranged between an ohmic load contact, in particular a drain contact, and a gate contact of the transistor for an injection of holes into a portion of the transistor channel. Further, a recombination zone implemented by a floating ohmic contact is provided for to improve the device performance.

Abstract: A semiconductor die includes a barrier layer of type III-V semiconductor material, a channel layer of type III-V semiconductor material disposed below the barrier layer, the channel layer forming a heterojunction with the barrier layer such that a two-dimensional charge carrier gas is disposed in the channel layer near the heterojunction, and a capacitor monolithically formed in the semiconductor die, wherein a dielectric medium of the capacitor includes a first section of the barrier layer.

Abstract: In an embodiment, a switching circuit is provided that includes a Group III nitride-based semiconductor body including a first monolithically integrated Group III nitride-based transistor device and a second monolithically integrated Group III nitride based transistor device that are coupled to form a half-bridge circuit and are arranged on a common foreign substrate having a common doping level. The switching circuit is configured to operate the half-bridge circuit at a voltage of at least 300 V.

Abstract: A semiconductor die includes a barrier layer of type III-V semiconductor material, a channel layer of type III-V semiconductor material disposed below the barrier layer, the channel layer forming a heterojunction with the barrier layer such that a two-dimensional charge carrier gas is disposed in the channel layer near the heterojunction, a high-electron mobility transistor disposed in a first lateral region of the semiconductor die, the high-electron mobility transistor comprising source and drain electrodes that each are in ohmic contact with the two-dimensional charge carrier gas and a gate structure that is configured to control a conductive connection between the source and drain electrodes, and a capacitor that is monolithically integrated into the semiconductor die and is disposed in a second lateral region of the semiconductor die, a dielectric medium of the capacitor includes a first section of the barrier layer.

Abstract: One or more semiconductor structures comprising a hole draining structure are provided. A semiconductor structure has a first layer formed over a substrate. The first layer has a first concentration of a metal material. The semiconductor structure has a second layer formed over the first layer. The second layer has a second concentration of the metal material different than the first concentration of the metal material. The semiconductor structure has a hole draining structure formed from a superlattice formed between the first layer and the second layer. The hole draining structure has a concentration of the metal material increasing towards the first layer and decreasing towards the second layer.

Abstract: A semiconductor die includes a barrier layer of type III-V semiconductor material, a channel layer of type III-V semiconductor material disposed below the barrier layer, the channel layer forming a heterojunction with the barrier layer such that a two-dimensional charge carrier gas is disposed in the channel layer near the heterojunction, a high-electron mobility transistor disposed in a first lateral region of the semiconductor die, the high-electron mobility transistor comprising source and drain electrodes that each are in ohmic contact with the two-dimensional charge carrier gas and a gate structure that is configured to control a conductive connection between the source and drain electrodes, and a capacitor that is monolithically integrated into the semiconductor die and is disposed in a second lateral region of the semiconductor die, a dielectric medium of the capacitor includes a first section of the barrier layer.

Abstract: A transistor package having four terminals includes a semiconductor transistor chip and a semiconductor diode chip. The semiconductor transistor chip includes a control electrode and a first load electrode on a first surface and a second load electrode on a second surface opposite the first surface. The semiconductor diode chip includes a first diode electrode on a first surface and a second diode electrode on a second surface opposite the first surface. The transistor package includes a first terminal electrically connected to the control electrode, a second terminal electrically connected to the first diode electrode, a third terminal electrically connected to the first load electrode and a fourth terminal electrically connected to the second load electrode. At least the first terminal, the second terminal and the third terminal protrude from one side of transistor package. The first terminal is arranged between the second terminal and the third terminal.

Abstract: A semiconductor device includes type IV semiconductor base substrate, first and second device areas that are electrically isolated from one another, a first region of type III-V semiconductor material formed over the first device area, a second region of type III-V semiconductor material formed over the second device area, the second region of type III-V semiconductor material being laterally electrically insulated from the first region of type III-V semiconductor material, a first high-electron mobility transistor integrally formed in the first region, and a second high-electron mobility transistor integrally formed in the second region. The first and second high-electron mobility transistors are connected in series. A source terminal of the first high-electron mobility transistor is electrically connected to the first device area. The first device area is electrically isolated from a subjacent intrinsically doped region of the base substrate by a first two-way voltage blocking device.

Abstract: A semiconductor device includes type IV semiconductor base substrate, first and second device areas that are electrically isolated from one another, a first region of type III-V semiconductor material formed over the first device area, a second region of type III-V semiconductor material formed over the second device area, the second region of type III-V semiconductor material being laterally electrically insulated from the first region of type III-V semiconductor material, a first high-electron mobility transistor integrally formed in the first region, and a second high-electron mobility transistor integrally formed in the second region. The first and second high-electron mobility transistors are connected in series. A source terminal of the first high-electron mobility transistor is electrically connected to the first device area. The first device area is electrically isolated from a subjacent intrinsically doped region of the base substrate by a first two-way voltage blocking device.

Abstract: In an embodiment, a switching circuit is provided that includes a Group III nitride-based semiconductor body including a first monolithically integrated Group III nitride-based transistor device and a second monolithically integrated Group III nitride based transistor device that are coupled to form a half-bridge circuit and are arranged on a common foreign substrate having a common doping level. The switching circuit is configured to operate the half-bridge circuit at a voltage of at least 300V.

Abstract: A semiconductor device includes type IV semiconductor base substrate, first and second device areas that are electrically isolated from one another, a first region of type III-V semiconductor material formed over the first device area, a second region of type III-V semiconductor material formed over the second device area, the second region of type III-V semiconductor material being laterally electrically insulated from the first region of type III-V semiconductor material, a first high-electron mobility transistor integrally formed in the first region, and a second high-electron mobility transistor integrally formed in the second region. The first and second high-electron mobility transistors are connected in series. A source terminal of the first high-electron mobility transistor is electrically connected to the first device area. The first device area is electrically isolated from a subjacent intrinsically doped region of the base substrate by a first two-way voltage blocking device.

Abstract: A semiconductor device includes a main bi-directional switch formed on a semiconductor substrate and having first and second gates, a first source electrically connected to a first voltage terminal, a second source electrically connected to a second voltage terminal, and a common drain. The semiconductor device further includes a discharge circuit having a plurality of individual transistors or an auxiliary bi-directional switch monolithically integrated with the main bi-directional switch and connected in a common source configuration to the semiconductor substrate. The plurality of individual transistors or the auxiliary bi-directional switch includes a first drain connected to the first source of the main bi-directional switch, a second drain connected to the second source of the main bi-directional switch, and first and second gates each decoupled from gate drive circuitry so that the first and the second gates are controlled at least passively and based on a state of the main bi-directional switch.