Power semiconductor devices comprise a gate pad, a plurality of gate fingers, and a first gate resistor and a first switch that are coupled between the gate pad and the gate fingers.

A semiconductor device includes a semiconductor part; first and second electrodes respectively on back and front surfaces of the semiconductor part; a control electrode provided inside a trench of the semiconductor part; a third electrode provided inside the trench; a diode element provided at the front surface of the semiconductor part; a resistance element provided on the front surface of the semiconductor part via an insulating film, the diode element being electrically connected to the second electrode; a first interconnect electrically connecting the diode element and the resistance element, the first interconnect being electrically connected to the third electrode; and a second interconnect electrically connecting the resistance element and the semiconductor part. The resistance element is connected in series to the diode element. The diode element is provided to have a rectifying property reverse to a current direction flowing from the resistance element to the second electrode.

A MOSFET with saturation contact. The MOSFET with saturation contact includes an n-doped source region, a source contact, a contact structure, which extends from the source contact to the n-doped source region, and forms with the source contact a first conductive connection and forms with the n-doped source region a second conductive connection, a barrier layer and an insulating layer. The contact structure includes a section between the first conductive connection and the second conductive connection, which is embedded between the barrier layer and the dielectric layer and is configured in such a way that a two-dimensional electron gas is formed therein.

This application provides an insulated gate bipolar transistor, a motor control unit, and a vehicle. The insulated gate bipolar transistor includes three device structure feature layers that are laminated. An IGBT device structure feature layer (10) and an RC-IGBT device structure feature layer (30) are respectively arranged on two sides of an SJ device structure feature layer (20). The RC-IGBT device structure feature layer (30) includes a collector (12) and a drain (13) that are disposed at a same layer. The insulated gate bipolar transistor further includes a first metal electrode (15) laminated with and electrically connected to the collector (12), and a second metal electrode (14) laminated with and electrically connected to the drain (13), and the first metal electrode (15) is electrically isolated from the second metal electrode (14).

A temperature sensor integrated in a transistor array, e.g., metal-oxide-semiconductor field-effect transistor (MOSFET) array, is provided. The integrated temperature sensor may include a doped well region formed in a substrate (e.g., SiC substrate), a resistor gate formed over the doped well region, first and second sensor terminals conductively coupled to the doped well region on opposite sides of the resistor gate. The integrated temperature sensor includes a gate driver to apply a voltage to the resistor gate that affects a resistance of the doped well region below the resistor gate, and temperature analysis circuitry to determine a resistance of a conductive path passing through the doped well region, and determine a temperature associated with the transistor array.

A semiconductor device includes a region of semiconductor material of a first conductivity type. A body region of a second conductivity type is in the region of semiconductor material. The body region includes a first segment with a first peak dopant concentration, and a second segment laterally adjacent to the first segment with a second peak dopant concentration. A source region of the first conductivity type is in the first segment but not in at least part of the second segment. An insulated gate electrode adjoins the first segment and is configured to provide a first channel region in the first segment, adjoins the second segment and is configured to provide a second channel region in the second segment, and adjoins the source region. During a linear mode of operation, current flows first in the second segment but not in the first segment to reduce the likelihood of thermal runaway.

A semiconductor device of the present invention includes a semiconductor region having a first main surface, wherein the semiconductor region includes: alternating n-type pillar layers and p-type pillar layers along the first main surface; a p-type first well layer located within each of the n-type pillar layers at a top surface of the n-type pillar layer; an n-type first source layer located within the first well layer at a top surface of the first well layer; a first side surface dielectric layer located on a side surface in a first trench located at each of boundaries between the n-type pillar layers and the p-type pillar layers, and being in contact with the first well layer and the first source layer; a first bottom surface dielectric layer located on a bottom surface in the first trench, and being at least partially in contact with one of the p-type pillar layers.

A power device includes a semiconductor substrate having first and second current carrying terminals on respective first and second opposing surfaces thereof. A silicided polysilicon temperature sensor and silicided polysilicon gate electrode are provided on the first surface. A source region of first conductivity type and a shielding region of second conductivity type are provided in the semiconductor substrate. The shielding region forms a P-N rectifying junction with the source region, and extends between the silicided polysilicon temperature sensor and the second current carrying terminal. A field oxide insulating region is provided, which extends between the shielding region and the silicided polysilicon temperature sensor.

In one general aspect, an apparatus can include a first trench disposed in a semiconductor region and including a gate electrode and a second trench disposed in the semiconductor region. The apparatus can include a mesa region disposed between the first trench and the second trench. The apparatus can include a source region segment of a first conductivity type disposed in a first side of the mesa region where the source region segment is included in a plurality of source region segments and where the plurality of source region segments are aligned along the longitudinal axis. The apparatus can include a body region segment of a second conductivity type disposed in a second side of the mesa region opposite the first side of the mesa region and having a portion disposed above the source region segment where the body region segment is included in a plurality of body region segments.

The present invention introduces a new shielded gate trench SBR (Super Barrier Rectifier) wherein an epitaxial layer having special MSE (multiple stepped epitaxial) layers with different doping concentrations decreasing in a direction from a substrate to a top surface of the epitaxial layer, wherein each of the MSE layers has an uniform doping concentration as grown. Forward voltage V.sub.f is significantly reduced with the special MSE layers. An integrated circuit comprising a SGT MOSFET and a SBR formed on a single chip obtains benefits of low on-resistance, low reverse recovery time and high avalanche capability from the special MSE layers.