A power semiconductor device and a method of manufacturing a power semiconductor device is provided, including a shield gate trench (SGT) metal-oxide semiconductor field-effect transistor (MOSFET). The present disclosure provides for a MOSFET with a reduced charge between the gate conductive region and the drain or collector region, in order to improve the switching efficiency of the MOSFET.

Methods and semiconductor structures are provided. A method according to the present disclosure includes receiving a workpiece that includes a first gate structure disposed over a first active region, a second gate structure disposed over a second active region, a first gate spacer extending along a sidewall of the first gate structure and disposed at least partially over a top surface of the first active region, a second gate spacer extending along a sidewall of the second gate structure and disposed at least partially over a top surface of the second active region, and a source/drain feature. The method also includes treating a portion of the first gate spacer and a portion of the second gate spacer with a remote radical of hydrogen or oxygen, removing the treated portions, and after the removal, depositing a metal fill material over the source/drain feature.

Wide bandgap trench gate semiconductor devices are provided. In one example, a semiconductor device includes a wide bandgap semiconductor structure. The wide bandgap semiconductor structure includes a drift region of a first conductivity type and a well region of a second conductivity type. The semiconductor device includes a gate trench in the wide bandgap semiconductor structure. The gate trench extends through the well region into the drift region. The semiconductor device includes a buried gate structure in the gate trench. The buried gate structure includes a gate polysilicon layer and a gate silicide layer.

A method for producing a semiconductor component includes providing a semiconductor body having a first semiconductor material extending to a first surface and at least one trench, the at least one trench extending from the first surface into the semiconductor body, a first insulation layer being arranged in the at least one trench. The method further includes forming a second insulation layer on the first surface having a recess that overlaps in a projection onto the first surface with the at least one trench, forming a mask region in the recess, etching the second insulation layer selectively to the mask region, depositing a third insulation layer over the first surface, and etching the third insulation layer so that a semiconductor mesa of the semiconductor body arranged next to the at least one trench is exposed at the first surface.

A power field effect transistor, a power field effect transistor device and a method of manufacturing a power field effect transistor are provided. During the manufacturing of the power field effect transistor, a body drive stage to manufacture the body region of the power field effect transistor is shortened to obtain a relatively low on resistance for the power field effect transistor. Before the implanting stage of the dopants of the body region, a pre body drive stage is introduced. During the pre body drive stage and the body drive stage sidewalls of a polysilicon layer of the power field effect transistor are oxidized to obtain a power field effect transistor which has at the sidewalls an oxidized polysilicon layer that is thick enough to prevent a premature current injection from the gate to the source regions of the power field effect transistor.

A semiconductor device includes a semiconductor body having a front side and a back side, and a trench included in the semiconductor body. The trench extends into the semiconductor body along an extension direction that points from the front side to the back side. The trench includes an electrode structure and an insulation structure, the insulation structure insulating the electrode structure from the semiconductor body and the electrode structure being arranged for receiving an electric signal from external of the semiconductor device. The electrode structure includes a first electrode and a second electrode in contact with the first electrode, the first electrode including a first electrode material and the second electrode including a second electrode material different from the first electrode material. The first electrode extends further along the extension direction as compared to the second electrode.

Semiconductor device fabrication method and devices are disclosed. The semiconductor power device is formed on a semiconductor substrate having a plurality of trench transistor cells each having a trench gate. Each of the trench gates having a thicker bottom oxide (TBO) formed by a REOX process on a polysilicon layer deposited on a bottom surface of the trenches.

Disclosed is a method for producing a transistor device and a transistor device. The method includes: forming a source region of a first doping type in a body region of a second doping type in a semiconductor body; and forming a low-resistance region of the second doping type adjoining the source region in the body region. Forming the source region includes implanting dopant particles of the first doping type using an implantation mask via a first surface of the semiconductor body into the body region. Implanting the doping particles of the first doping type includes a tilted implantation.

Trench MOSFET with self-aligned body contact with spacer. In accordance with an embodiment of the present invention, a semiconductor device includes a semiconductor substrate, and at least two gate trenches formed in the semiconductor substrate. Each of the trenches comprises a gate electrode. The semiconductor device also includes a body contact trench formed in the semiconductor substrate between the gate trenches. The body contact trench has a lower width at the bottom of the body contact trench and an ohmic body contact implant beneath the body contact trench. The horizontal extent of the ohmic body contact implant is at least the lower width of the body contact trench.

Forming a semiconductor device on a semiconductor substrate having a substrate top surface includes: forming a gate trench extending from the substrate top surface into the semiconductor substrate; forming a gate electrode in the gate trench; forming a curved sidewall portion along at least a portion of a sidewall of the gate trench; forming a body region adjacent to the gate trench; forming a source region embedded in the body region, including disposing source material in a region that is along at least a part of the curved sidewall portion; forming a gate top dielectric layer over the gate electrode and having a top side that is below at least a portion of the source region; and forming a metal layer over at least a portion of a gate trench opening and at least a portion of the source region.