In an embodiment, a method of forming a field plate in an elongate active trench of a transistor device is provided. The elongate active trench includes a first insulating material lining the elongate active trench and surrounding a gap and first conductive material filling the gap. The method includes selectively removing a first portion of the first insulating material using a first etch process, selectively removing a portion of the first conductive material using a second etch process, and forming a field plate in a lower portion of the elongate active trench and selectively removing a second portion of the first insulating material using a third etch process. The first etch process is carried out before the second etch process and the second etch process is carried out before the third etch process.

A semiconductor device has an impurity region covering a bottom of a gate trench and a column region. A bottom of the column region is deeper than a bottom of the gate trench. The impurity region is arranged between the gate trench and the column region. This structure can improve the characteristics of the semiconductor device.

The present application relates to a semiconductor transistor device that includes a Schottky diode electrically connected in parallel to a body diode formed between a body region and a drift region. A diode junction of the Schottky diode is formed adjacent to the drift region and is arranged vertically above a lower end of the body region.

A trench metal-oxide-semiconductor field-effect transistor (MOSFET) device comprises an active cell area including a plurality of superjunction trench power MOSFETs, and a Schottky diode area including a plurality of Schottky diodes formed in the drift region having the superjunction structure. Each of the integrated Schottky diodes includes a Schottky contact between a lightly doped semiconductor layer and a metallic layer.

A charge-balance power device includes a semiconductor body having a first conductivity type. A trench gate extends in the semiconductor body from a first surface toward a second surface. A body region has a second conductivity type that is opposite the first conductivity type, and the body region faces the first surface of the semiconductor body and extends on a first side and a second side of the trench gate. Source regions having the first conductivity type extend in the body region and face the first surface of the semiconductor body. A drain terminal extends on the second surface of the semiconductor body. The device further comprises a first and a second columnar region having the second conductivity, which extend in the semiconductor body adjacent to the first and second sides of the trench gate, and the first and second columnar regions are spaced apart from the body region and from the drain terminal.

A shield trench power device such as a trench MOSFET or IGBT employs a gate structure with an underlying polysilicon shield region overlying a shield region in an epitaxial or crystalline layer of the device. The polysilicon region may be laterally confined by spacers in a gate trench and may contact or be isolated from the underlying shield region. Alternatively, the polysilicon region may be replaced with an insulating region.

A semiconductor device is described. The semiconductor device includes: a semiconductor substrate; an electrode structure on or in the semiconductor substrate, the electrode structure including an electrode and an insulating material that separates the electrode from the semiconductor substrate; and a strain-inducing material embedded in the electrode. The electrode structure adjoins a region of the semiconductor substrate through which current flows in a first direction during operation of the semiconductor device. The electrode is under either tensile or compressive stress in the first direction. The strain-inducing material either enhances or at least partly counteracts the stress of the electrode in the first direction. Methods of producing the semiconductor device are also described.

A semiconductor device is described. The semiconductor device includes: a Si substrate having a first main surface; a plurality of gate trenches extending from the first main surface into the Si substrate; a semiconductor mesa between adjacent gate trenches; a first interlayer dielectric on the first main surface; a plurality of first metal contacts extending through the first interlayer dielectric and contacting gate electrodes disposed in the gate trenches; a plurality of second metal contacts extending through the first interlayer dielectric and contacting the semiconductor mesas; and an air gap or a dielectric material having a lower dielectric constant than the first interlayer dielectric between adjacent first and second metal contacts. Methods of producing the semiconductor device are also described.

A semiconductor device includes: a compound semiconductor layer having a first compound semiconductor layer and a second compound semiconductor layer having a higher melting point than the first compound semiconductor layer; and an insulation gate on the second compound semiconductor layer. The compound semiconductor layer further includes: a drift region; a source region; and a body region between the drift region and the source region. The insulation gate faces the body region. The body region bridges over both the first compound semiconductor layer and the second compound semiconductor layer.

A VDMOS device and a manufacturing method therefor. The method comprises: forming a groove in a semiconductor substrate, wherein the groove comprises a first groove area, a second groove area and a third groove area communicating with the first groove area and the second groove area, and the width of the first groove area is greater than the widths of the second groove area and the third groove area; forming an insulation layer on the semiconductor substrate; forming a first polycrystalline silicon layer on the insulation layer; removing some of the first polycrystalline silicon layer; the first polycrystalline silicon layer forming in the first groove being used as a first electrode of a deep gate; removing all the insulation layer located on the surface of the semiconductor substrate and some of the insulation layer located in the groove; forming a gate oxide layer on the semiconductor substrate; forming a second polycrystalline silicon layer on the gate oxide layer; removing some of the second polycrystalline silicon layer; and the second polycrystalline silicon layer forming in the groove being used as a second electrode of a shallow gate.