An integrated circuit structure includes a semiconductor substrate, a first source/drain feature, a second source/drain feature, a gate dielectric layer, a gate electrode, a field plate electrode, and a dielectric layer. The semiconductor substrate has a well region and a drift region therein. The first source/drain feature is in the well region. The second source/drain feature is in the semiconductor substrate. The drift region is between the well region and the second source/drain feature. The gate dielectric layer is over the well region and the drift region. The gate electrode is over the gate dielectric layer and vertically overlapping the well region. The field plate electrode is over the gate dielectric layer and vertically overlapping the drift region. The dielectric layer is between the gate electrode and the field plate electrode. A top surface of the gate electrode is free of the dielectric layer.

An apparatus includes lightly doped drain regions vertically extending into a semiconductor substrate. A channel region is horizontally interposed between the lightly doped drain regions, and source/drain regions vertically extend into the lightly doped drain regions. Breakdown-enhancement implant intrusion regions are within the lightly doped drain regions and are horizontally interposed between the channel region and the source/drain regions. The breakdown enhancement implant regions have a different chemical species than the lightly doped drain regions and have upper boundaries vertically underlying upper boundaries of the lightly doped drain regions. The apparatus also has a gate structure vertically overlying the channel regions and it is horizontally interposed between the breakdown-enhancement implant regions. Memory devices, electronic systems, and methods of forming microelectronic devices are also described.

A microelectronic device including an integrated boot diode and a depleted mode LDMOS transistor with a charge balance layer isolated from the body region and electrically in contact with a substrate. The connection of the charge balance layer of the depleted mode LDMOS transistor directly to the substrate or ground reference eliminates body diode turn-on from the body of the transistor to the drain which typically happens above approximately 0.7 volts. In addition, the depleted mode LDMOS transistor may separate a source contact from a body contact which allows a negative bias of the body with respect to the source. Typically, the source voltage is limited to approximately 7 volts before parasitic PNP turn on becomes a factor. By negatively biasing the body with respect to the source, the maximum source voltage of the depleted mode LDMOS transistor without PNP parasitic turn-on may be increased to approximately 30 V.

A high-voltage device structure and methods of forming the same are described. In some embodiments, the structure includes a deep well region of a first conductivity type disposed in a substrate, a doped region disposed on the deep well region; a well region of the first conductivity type surrounding the deep well region and the doped region; a source region disposed on the well region, a drain region disposed on the doped region, and a first pickup region of the first conductivity type disposed on the well region. The first pickup region is laterally in contact with the source region, and the first pickup region, the well region, and the deep well region are electrically connected.

According to one aspect of the present disclosure, a semiconductor device includes a substrate having a first type dopant. In some embodiments, the semiconductor device also includes an epitaxial layer above the substrate, having a second type dopant and a top region. In some embodiments, the semiconductor device also includes a trench in the top region of the epitaxial layer; at least one doped ring implanted in the epitaxial layer below the trench; and a dielectric material filling within the trench. In some embodiments, there is a twelve-sided body tie in the epitaxial layer, wherein the sides of the twelve-sided body tie are not all equal to each other.

The present invention relates to an LDMOS device and a method of forming the device, in which a barrier layer includes n etch stop layers. Insulating layers are formed between adjacent etch stop layers. Since an interlayer dielectric layer and the insulating layers are both oxides that differ from the material of the etch stop layers, etching processes can be stopped at the n etch stop layers when they are proceeding in the oxides, thus forming n field plate holes terminating at the respective n etch stop layers. A lower end of the first field plate hole proximal to a gate structure is closest to a drift region, and a lower end of the n-th field plate hole proximal to a drain region is farthest from the drift region. With this arrangement, more uniform electric field strength can be obtained around front and rear ends of the drift region, resulting in an effectively improved electric field distribution throughout the drift region and thus in an increased breakdown voltage.

A structure of a semiconductor device, including a substrate, is provided. A first gate insulating layer is disposed on the substrate. A second gate insulating layer is disposed on the substrate. The second gate insulating layer is thicker than the first gate insulating layer and abuts the first gate insulating layer. A gate layer has a first part gate on the first gate insulating layer and a second part gate on the second gate insulating layer. A dielectric layer has a top dielectric layer and a bottom dielectric layer. The top dielectric layer is in contact with the gate layer, and the bottom dielectric layer is in contact with the substrate. A field plate layer is disposed on the dielectric layer and includes a depleted region, and is at least disposed on the bottom dielectric layer. A method for fabricating the semiconductor device is provided too.

Structures for an extended-drain metal-oxide-semiconductor device and methods of forming a structure for an extended-drain metal-oxide-semiconductor device. The structure comprises a semiconductor layer, a source region, a drain region, and a gate positioned between the source region and the drain region. The gate includes a gate conductor layer, a first gate dielectric layer having a first thickness, and a second gate dielectric layer having a second thickness greater than the first thickness. The first gate dielectric layer is disposed on a top surface of the semiconductor layer, and the second gate dielectric layer includes a first section on the top surface of the semiconductor layer and a second section adjacent to a sidewall of the semiconductor layer. The gate conductor layer has an overlapping relationship with the first gate dielectric layer, the first section of the second gate dielectric layer, and the second section of the second gate dielectric layer.

A SiC semiconductor device having high pressure resistance properties is disclosed. The present invention provides a SiC semiconductor device comprising: a SiC substrate having a first surface and a second surface; an insulating area formed on the second surface side inside the SiC substrate; and a plurality of semiconductor areas including a source area, a base area, and a drain area formed along the first surface on the insulating area, wherein the SiC semiconductor device has a P/N junction parallel to the first surface, the P/N junction extending from the base area toward the drain area on the insulating area and being formed by a first auxiliary region of a first conductive type which is the same conductive type as the source area and a second auxiliary region of a second conductive type which is opposed to the first conductive type.

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.