Disclosed is a high voltage semiconductor device. More particularly, a high voltage semiconductor device is disclosed, including a slope compensating structure on at least a portion of an outermost surface of a gate spacer defining a sidewall of a gate structure, thereby reducing or preventing electric field concentration in a corner of a gate field plate, and thus improving reliability of the device.

Various embodiments of the present disclosure are directed towards an integrated chip including a field plate. A gate structure overlies a substrate between a source region and a drain region. A drift region is disposed laterally between the gate structure and the drain region. A first dielectric layer overlies the substrate. A field plate is disposed within the first dielectric layer between the gate structure and the drain region. A conductive wire overlies the first dielectric layer and contacts the field plate. At least a portion of the conductive wire directly overlies a first sidewall of the drift region.

An integrated circuit (IC) structure and a field plate are disclosed. The IC structure and field plate may find advantageous application with, for example, extended drain metal-oxide semiconductor (EDMOS) transistors. The IC structure includes a transistor including a metal gate structure and a drain extension region extending laterally from partially under the metal gate structure to a drain region. A metal field plate is over the drain extension region. Due to being formed simultaneously as part of a gate-last formation approach, the metal field plate has an upper surface coplanar with an upper surface of the metal gate structure. A field plate contact may be on the metal field plate.

A semiconductor device includes at least one transistor, a shallow well region, a guard ring, and a plurality of first and second doped regions. The transistor is on a substrate and includes a source structure, a gate structure, and a drain structure. The shallow well region surrounds the transistor. The shallow well region has a first conductivity type. The guard ring surrounds the shallow well region. The guard ring has the first conductivity type. The first and second doped regions are disposed on the guard ring and surround the well region. The first doped regions and the second doped regions are alternately arranged in a shape of a loop. Each of the first doped regions and each of the second doped regions have opposite conductivity types.

Various embodiments of the present disclosure are directed towards an integrated chip. The integrated chip includes a semiconductor substrate having a device substrate overlying a handle substrate and an insulator layer disposed between the device substrate and the handle substrate. A gate electrode overlies the device substrate between a drain region and a source region. A conductive via extends through the device substrate and the insulator layer to contact the handle substrate. A first isolation structure is disposed within the device substrate and comprises a first isolation segment disposed laterally between the gate electrode and the conductive via. A contact region is disposed within the device substrate between the first isolation segment and the conductive via. A conductive gate electrode directly overlies the first isolation segment and is electrically coupled to the contact region.

The present invention relates to an LDMOS device and a method for preparing same. When a field plate hole is formed by etching an interlayer dielectric layer, the etching of the field plate hole is stopped on a blocking layer by means of providing the blocking layer between a semiconductor base and the interlayer dielectric layer. Since the blocking layer is provided with at least one layer of an etch stop layer, and steps are formed on the surface of the blocking layer, at least two levels of formed hole field plates are distributed in a step shape, and lower ends of the first level of hole field plates to the nth level of hole field plates are gradually further away from the drift area in the direction from a gate structure to a drain area.

A semiconductor power device having shielded gate structure in an active area and trench field plate termination surrounding the active area is disclosed. A Zener diode connected between drain metal and source metal or gate metal for functioning as a SD or GD clamp diode. Trench field plate termination surrounding active area wherein only cell array located will not cause BV degradation when SD or GD poly clamped diode integrated.

Various embodiments of the present disclosure are directed towards an integrated chip. The integrated chip includes a semiconductor substrate having a device substrate overlying a handle substrate and an insulator layer disposed between the device substrate and the handle substrate. A gate electrode overlies the device substrate between a drain region and a source region. A conductive via extends through the device substrate and the insulator layer to contact the handle substrate. A first isolation structure is disposed within the device substrate and comprises a first isolation segment disposed laterally between the gate electrode and the conductive via. A contact region is disposed within the device substrate between the first isolation segment and the conductive via. A conductive gate electrode directly overlies the first isolation segment and is electrically coupled to the contact region.

A semiconductor device includes: cell and termination regions; a first electrode; a semiconductor part on the first electrode; an insulating film on the semiconductor part in the termination region; mutually-separated second electrodes on the insulating film arranged in a direction from a center toward an outer perimeter of the semiconductor part when viewed from above; a first floating electrode in the insulating film overlapping a gap between an adjacent pair of the second electrodes when viewed from above, and facing one of the pair via the insulating film; and a second floating electrode in the insulating film and separated from and overlapping the first floating electrode in the gap when viewed from above, and facing the other of the pair of second electrodes via the insulating film, wherein the overlapping portion of the second floating electrode is positioned below a portion of the first floating electrode overlapping the gap.

An integrated circuit (IC) structure and a field plate are disclosed. The IC structure and field plate may find advantageous application with, for example, extended drain metal-oxide semiconductor (EDMOS) transistors. The IC structure includes a transistor including a metal gate structure and a drain extension region extending laterally from partially under the metal gate structure to a drain region. A metal field plate is over the drain extension region. Due to being formed simultaneously as part of a gate-last formation approach, the metal field plate has an upper surface coplanar with an upper surface of the metal gate structure. A field plate contact may be on the metal field plate.