This power supply IC is a semiconductor integrated circuit device serving as a main part for controlling a switching power supply and is formed by integrating a feedback resistor and an output feedback control unit on a single semiconductor substrate, said feedback resistor generating a feedback voltage by dividing the output voltage of the switching power supply (or the induced voltage appearing across an auxiliary winding provided on the primary side of a transformer included in an insulation-type switching power supply), said output feedback control unit performing output feedback control of the switching power supply in accordance with the feedback voltage. The feedback resistor is a polysilicon resistor having a withstand voltage of 100 V or more. A high-voltage region having higher withstand voltage in the substrate thickness direction than the other region is formed in the semiconductor substrate, and the feedback resistor is formed on the high-voltage region.

A semiconductor device includes a layer of a first semiconducting material, where the first semiconducting material is epitaxially grown to have a crystal structure of a first substrate. The semiconductor device further includes a layer of a second semiconducting material disposed adjacent to the layer of the first semiconducting material to form a heterojunction with the layer of the first semiconducting material. The semiconductor device further includes a first component that is electrically coupled to the heterojunction, and a second substrate that is bonded to the layer of the first semiconducting material.

In an embodiment, a transistor device comprises a semiconductor body comprising a plurality of transistor cells comprising a drift region of a first conductivity type, a body region of a second conductivity type forming a first pn junction with the drift region, the second conductivity type opposing the first conductivity type, a source region of the first conductivity type forming a second pn junction with the body region, a columnar field plate trench extending into a major surface of a semiconductor body and comprising a columnar field plate and a gate trench structure extending into the major surface of the semiconductor body and comprising a gate electrode. At least one of the depth and doping level of the body region locally varies within the transistor cell to improve VGSTH homogeneity within the transistor cell.

A semiconductor device includes a channel layer, a barrier layer, source contact and a drain contact, a doped group III-V layer, and a gate electrode. The barrier layer is positioned above the channel layer. The source contact and the drain contact are positioned above the barrier layer. The doped group III-V layer is positioned above the barrier layer and between the first drain contact and the first source contact. The first doped group III-V layer has a first non-vertical sidewall and a second non-vertical sidewall. The gate electrode is positioned above the doped group III-V layer and has a third non-vertical sidewall and a fourth non-vertical sidewall. A horizontal distance from the first non-vertical sidewall to the third non-vertical sidewall is different than a horizontal distance from the second non-vertical sidewall to the fourth non-vertical sidewall.

An SOI lateral homogenization field high voltage power semiconductor device, and a manufacturing method and application thereof are provided. The device includes a type I conductive semiconductor substrate, a type II conductive drift region, a type I field clamped layer, type I and type II conductive well regions, the first dielectric oxide layer forming a field oxide layer, the second dielectric oxide layer forming a gate oxide layer, a type II conductive buried dielectric layer, a type II conductive source heavily doped region, a type II conductive drain heavily doped region. The first dielectric oxide layer and the floating field plate polysilicon electrodes form a vertical floating field plate distributed throughout the type II conductive drift region to form a vertical floating equipotential field plate array. When the device is in on-state, high doping concentration can be realized by the full-region depletion effect form the vertical field plate arrays.

A transistor includes a trench formed in a semiconductor substrate. A conductive spacer is formed in the trench and offset from a first sidewall of the trench. A dielectric material is formed in the trench and surrounds the conductive spacer. A drift region is formed in the semiconductor substrate adjacent to the first sidewall and a first portion of a second sidewall of the trench. A drain region is formed in the drift region adjacent to a second portion of the second sidewall. A first gate region overlaps a portion of the drift region and is formed separate from the conductive spacer.

A semiconductor device includes a semiconductor part, first to third electrodes, and first and second control electrodes. The semiconductor part is provided between the first and second electrodes. On the second electrode side of the semiconductor part, the first control electrode and the third electrode are provided in a first trench, and the second control electrode is provided in a second trench. The first control electrode is provided between the second and third electrode. In a first direction from the first control electrode toward the second control electrode, the first trench has first and second widths. The first width is a combined width of the third electrode and insulating portions provided on both sides of the third electrode. The second width is a combined width of the first control electrode and the gate insulating films on both sides thereof. The first width is greater than the second width.

A power semiconductor device includes a P-type substrate, an N-type well region, a P-type body region, a gate oxide layer, a polysilicon gate, a first oxide layer, a first N+ contact region, a first P+ contact region, drain metal, a first-type doped region, and a gate oxide layer. An end of the P-type body region is flush with or exceeds an end of the polysilicon gate, wherein C.sub.gd of the power semiconductor device is reduced and a switching frequency of the power semiconductor device is increased. A polysilicon field plate connected with a source is introduced over a drift region that is not only shield an influence of the polysilicon gate on the drift region, thereby eliminating C.sub.gd caused by overlapping of traditional polysilicon gate and drift region, but also enable the power semiconductor device to have strong robustness against an hot carrier effect.

A microelectronic device includes a doped region of semiconductor material having a first region and an opposite second region. The microelectronic device is configured to provide a first operational potential at the first region and to provide a second operational potential at the second region. The microelectronic device includes field plate segments in trenches extending into the doped region. Each field plate segment is separated from the semiconductor material by a trench liner of dielectric material. The microelectronic device further includes circuitry electrically connected to each of the field plate segments. The circuitry is configured to apply bias potentials to the field plate segments. The bias potentials are monotonic with respect to distances of the field plate segments from the first region of the doped region.

An LDMOS device and a method for forming the LDMOS device are provided. The LDMOS device includes: a substrate formed with a source region, a drain region and a drift region; a gate structure; a silicide block layer; a first conductive structure having one end electrically connected with the source region, a second conductive structure having one end electrically connected with the drain region; a first metal interconnecting structure electrically connected with the other end of the first conductive structure, a second metal interconnecting structure electrically connected with the other end of the second conductive structure; a third conductive structure having one end disposed on a surface of the silicide block layer; and a third metal interconnecting structure electrically connected with the other end of the third conductive structure. The LDMOS device has increased breakdown voltage, and reduced on-resistance, and its preparation process is safer and easier to control.