Semiconductor device structures and related fabrication methods are provided. An exemplary semiconductor device structure includes a body region of semiconductor material having a first conductivity type, a source region of semiconductor material having a second conductivity type within the body region, a junction isolation region of semiconductor material having the second conductivity type, a drain region of semiconductor material having the second conductivity type, and first and second drift regions of semiconductor material having the second conductivity type. The first drift region resides laterally between the drain region and the junction isolation region, the junction isolation region resides laterally between the first drift region and the second drift region, and the second drift region resides laterally between the body region and the junction isolation region.

A semiconductor device includes: a silicon layer having a thickness in a range of 2 m to 200 m between a frontside and a backside of the silicon layer; a first device region and a second device region laterally isolated from one another in the silicon layer by an isolation structure that extends from the frontside to the backside of the silicon layer; a first insulation layer on the frontside of the silicon layer; a first patterned metallization on the first insulation layer; a second insulation layer on the backside of the silicon layer; and a second patterned metallization on the second insulation layer. The first patterned metallization provides lateral electrical routing along the frontside of the silicon layer. The second patterned metallization provides lateral electrical routing along the backside of the silicon layer. Additional embodiments of semiconductor devices and methods of producing the semiconductor devices are also described.

The invention provides a metal oxide semiconductor (MOS) capacitor structure, which includes a counter-doping region in the channel region directly below the gate. Between the deep ion well and the counter-doping region is a semiconductor region. The doping concentration of the semiconductor region is lower than that of the deep ion well. The P-type well ion implantation processes in the active region of the device can be omitted, so the production cost is lower, and the dosage of the counter-doping region can be reduced, which improves the time-dependent dielectric collapse (TDDB) issue.

A semiconductor device is provided. The semiconductor device may include a silicon carbide substrate, a silicon layer formed at a first side of the silicon carbide substrate, a gate oxide layer formed on the silicon layer, a gate terminal formed on the gate oxide layer, a drain terminal formed at a second side of the silicon carbide substrate opposite the first side, and a source terminal formed at the first side of the silicon carbide substrate, and at opposite ends of the silicon layer.

A semiconductor structure and a method for forming a semiconductor structure are provided. The semiconductor structure includes: a substrate; a doped region within the substrate; a pair of source/drain regions extending along a first direction on opposite sides of the doped region; a gate electrode disposed in the doped region, wherein the gate electrode has a plurality of first segments between the pair of source/drain regions; and a protection structure overlapping the gate electrode.

A vertical field effect transistor, including a drift region having a first conductivity type, a trench structure on or above the drift region, a shielding structure, and a source/drain electrode. The trench structure includes at least one side wall at which a field effect transistor (FET) channel region is formed. The FET channel region includes a III-V heterostructure for forming a two-dimensional electron gas at a boundary surface of the III-V heterostructure. The shielding structure is situated laterally adjacent to the at least one side wall of the trench structure and extends vertically into the drift region or vertically further in the direction of the drift region than the trench structure. The shielding structure has a second conductivity type that differs from the first conductivity type. The source/drain electrode is electroconductively connected to the III-V heterostructure of the trench structure and to the shielding structure.

A structure comprises a p-type substrate, a deep n-type well and a deep p-type well. The deep n-type well is adjacent to the p-type substrate and has a first conductive path to a first terminal. The deep p-type well is in the deep n-type well, is separated from the p-type substrate by the deep n-type well, and has a second conductive path to a second terminal. A first n-type well is over the deep p-type well. A first p-type well is over the deep p-type well.

A semiconductor device includes a semiconductor body including first and second lateral surfaces. A first device region includes a drift region of a first conductivity type, and a drift current control region of a second conductivity type being spaced apart from the second lateral surface by the drift region. A second device region includes a barrier layer, and a buffer layer having a different band gap than the barrier layer so that a two-dimensional charge carrier gas channel arises along an interface between the buffer layer and the barrier layer. An electrically conductive substrate contact forms a low ohmic connection between the two-dimensional charge carrier gas channel and the drift region. A gate structure is configured to control a conduction state of the two-dimensional charge carrier gas. The drift current control region is configured to block a vertical current in the drift region via a space-charge region.

A semiconductor device includes a semiconductor body including first and second lateral surfaces. A first device region includes a drift region of a first conductivity type, and a drift current control region of a second conductivity type being spaced apart from the second lateral surface by the drift region. A second device region includes a barrier layer, and a buffer layer having a different band gap than the barrier layer so that a two-dimensional charge carrier gas channel arises along an interface between the buffer layer and the barrier layer. An electrically conductive substrate contact forms a low ohmic connection between the two-dimensional charge carrier gas channel and the drift region. A gate structure is configured to control a conduction state of the two-dimensional charge carrier gas. The drift current control region is configured to block a vertical current in the drift region via a space-charge region.

A MOS transistor structure is provided. The MOS transistor structure includes a semiconductor substrate having an active area including a first edge and a second edge opposite thereto. A gate layer is disposed on the active area of the semiconductor substrate and has a first edge extending across the first and second edges of the active area. A source region having a first conductivity type is in the active area at a side of the first edge of the gate layer and between the first and second edges of the active area. First and second heavily doped regions of a second conductivity type are in the active area adjacent to the first and second edges thereof, respectively, and spaced apart from each other by the source region.