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.

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.

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.

A semiconductor device includes an active region, a LOCOS region formed within the active region and that extends vertically above a top surface of the active region, a gate region formed above the top surface of the active region, and a polysilicon resistor having a bottom surface that is offset vertically and physically isolated from a top surface of the LOCOS region. The active region includes a source region laterally disposed from the gate region, a drain region laterally disposed from the gate region, and a drift region laterally disposed between the gate region and the drain region. The polysilicon resistor is formed above the drift region. The active region further includes a first charge balance region formed in the active region below the drift region.

A semiconductor device includes an active region, a LOCOS region formed within the active region and that extends vertically above a top surface of the active region, a gate region formed above the top surface of the active region, and a polysilicon resistor having a bottom surface that is offset vertically and physically isolated from a top surface of the LOCOS region. The active region includes a source region laterally disposed from the gate region, a drain region laterally disposed from the gate region, and a drift region laterally disposed between the gate region and the drain region. The polysilicon resistor is formed above the drift region. The active region further includes a first charge balance region formed in the active region below the drift region.

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.

A method for eliminating divot formation includes forming an isolation layer; forming a conduction layer which has an upper inclined boundary with the isolation layer such that the conduction layer has a portion located above a portion of the isolation layer at the upper inclined boundary; etching back the isolation layer; and etching back the conduction layer after etching back the isolation layer such that a top surface of the etched conduction layer is located at a level lower than a top surface of the etched isolation layer.

The present disclosure relates to an integrated chip. The integrated chip includes a source region disposed within a substrate, and a drain region disposed within the substrate and separated from the source region. A plurality of separate isolation structures are disposed within the substrate. The plurality of separate isolation structures have outermost sidewalls that face one another and that are separated from one another. A gate electrode is disposed within the substrate. The gate electrode includes a base region disposed between the source region and the plurality of separate isolation structures and a plurality of gate extensions extending outward from a sidewall of the base region to over the plurality of separate isolation structures.

An apparatus includes a substrate of a first conductivity, an extended drain region of a second conductivity formed over the substrate, a body region of the first conductivity formed in the extended drain region, a source region of the second conductivity formed in the body region, a drain region of the second conductivity formed in the extended drain region, a first dielectric layer formed over the body region and the extended drain region, a second dielectric layer formed over the extended drain region, and between the first dielectric layer and the drain region, a first gate formed over the first dielectric layer, and a second gate formed over the second dielectric layer, wherein the second gate is electrically connected to the source region.