A semiconductor device includes a semiconductor substrate. A well resistor is in the semiconductor substrate. A field plate is above the well resistor. An insulator is between the well resistor and the field plate. The well resistor includes a first terminal and a second terminal. The field plate may be coupled to the first terminal or the second terminal.

A semiconductor device according to an embodiment includes first to third semiconductor regions, a structure body, a gate electrode, and a high resistance part. The structure body includes an insulating part and a conductive part. The insulating part is arranged with the third semiconductor region, the second semiconductor region, and a portion of the first semiconductor region. The conductive part is located in the insulating part. The conductive part includes a portion facing the first semiconductor region. The high resistance part is located in the first semiconductor region and has a higher electrical resistance than the first semiconductor region. A plurality of the structure bodies includes first to third structure bodies. The second and third structure bodies are next to the first structure body. The high resistance part overlaps a circle center of an imaginary circle passing through centers of the first to third structure bodies.

A lateral superjunction MOSFET device includes multiple transistor cells connected to a lateral superjunction structure, each transistor cell including a conductive gate finger, a source region finger, a body contact region finger and a drain region finger arranged laterally within each transistor cell. Each of the drain region fingers, the source region fingers and the body contact region fingers is a doped region finger having a termination region at an end of the doped region finger. The lateral superjunction MOSFET device further includes a termination structure formed in the termination region of each doped region finger and including one or more termination columns having the same conductivity type as the doped region finger and positioned near the end of the doped region finger. The one or more termination columns extend through the lateral superjunction structure and are electrically unbiased.

Field-plate structures are disclosed for electrical field management in semiconductor devices. A field-plate semiconductor device comprises a semiconductor substrate, a first ohmic contact and a second ohmic contact disposed over the semiconductor substrate, one or more coupling capacitors, and one or more capacitively-coupled field plates disposed over the semiconductor substrate between the first ohmic contact and the second ohmic contact. Each of the capacitively-coupled field plates is capacitively coupled to the first ohmic contact through one of the coupling capacitors, the coupling capacitor having a first terminal electrically connected to the first ohmic contact and a second terminal electrically connected to the capacitively-coupled field plate.

The present invention generally relates to a structure and manufacturing of a power field effect transistor (FET). The present invention provides a planar power metal oxide semiconductor field effect transistor (MOSFET) structure and an insulated gate bipolar transistor (IGBT) structure comprising a split gate and a semi-insulating field plate. The present invention also provides manufacturing methods of the structures.

A lateral power integrated device includes a source region and a drain region disposed in a semiconductor layer and spaced apart from each other in a first direction, a drift region disposed in the semiconductor layer and surrounding the drain region, a channel region arranged between the source region and the drift region in the first direction, a plurality of planar insulation field plates disposed over the drift region and spaced apart from each other in a second direction, a plurality of trench insulation field plates disposed in the drift region, a gate insulation layer formed over the channel region, and a gate electrode formed over the gate insulation layer. Each of the trench insulation field plates is disposed between the planar insulation field plates in the second direction.

A termination structure for a nitride-based Schottky diode includes a guard ring formed by an epitaxially grown P-type nitride-based compound semiconductor layer and dielectric field plates formed on the guard ring. The termination structure is formed at the edge of the anode electrode of the Schottky diode and has the effect of reducing electric field crowding at the anode electrode edge, especially when the Schottky diode is reverse biased. In one embodiment, the P-type epitaxial layer includes a step recess to further enhance the field spreading effect of the termination structure.

A semiconductor device having a voltage resistant structure in a first aspect of the present invention is provided, comprising a semiconductor substrate, a semiconductor layer on the semiconductor substrate, a front surface electrode above the semiconductor layer, a rear surface electrode below the semiconductor substrate, an extension section provided to a side surface of the semiconductor substrate, and a resistance section electrically connected to the front surface electrode and the rear surface electrode. The extension section may have a lower permittivity than the semiconductor substrate. The resistance section may be provided to at least one of the upper surface and the side surface of the extension section.

A first sense resistor is connected between a fourth terminal of a power source potential of a high-potential region and a first terminal of a ground potential. A second sense resistor is connected between a third terminal of a reference potential of the high-potential region and the first terminal. A comparator is disposed in a low-potential region and uses the ground potential as a reference potential for operation. The comparator compares a voltage between an intermediate potential point of the first sense resistor and an intermediate potential point of the second sense resistor with a predetermined reference voltage. The output of the comparator is input through a control circuit and a level shift circuit to a high-side drive circuit driving an upper-arm IGBT. The output of the comparator is input to a driver circuit driving a lower-arm IGBT.

A lateral superjunction MOSFET device includes a gate structure and a first column connected to the lateral superjunction structure. The lateral superjunction MOSFET device includes the first column to receive current from the channel when the MOSFET is turned on and to distribute the channel current to the lateral superjunction structure functioning as the drain drift region. In some embodiment, the MOSFET device includes a second column disposed in close proximity to the first column. The second column disposed near the first column is used to pinch off the first column when the MOSFET device is to be turned off and to block the high voltage being sustained by the MOSFET device at the drain terminal from reaching the gate structure. In some embodiments, the lateral superjunction MOSFET device further includes termination structures for the drain, source and body contact doped region fingers.