A semiconductor device includes an active region configured by a first MOS structure region and a second MOS structure region, a gate ring region surrounding a periphery of the active region, a first ring region surrounding a periphery of the gate ring region, a second ring region surrounding a periphery of the first ring region, and a termination region surrounding a periphery of the second ring region. The semiconductor device has first first-electrodes in the first MOS structure region, second first-electrodes in the second MOS structure region, a third first-electrode in the first ring region, and a fourth first-electrode in the second ring region. The third first-electrode has a potential equal to that of the second first-electrodes, and the fourth first-electrode has a potential equal to that of the first first-electrodes.

A semiconductor device includes first and second electrodes, first to third semiconductor regions, first and second conductive parts, a first conductive region, a first electrode region, and a conductive layer. The first-conductivity-type third semiconductor region is on the second-conductivity-type second semiconductor region, which is on a portion of the first-conductivity-type first semiconductor region, which is on and electrically connected to the first electrode. A portion of the first conductive part faces the second semiconductor region side surface. A portion of the second conductive part faces the first semiconductor region side surface. The second electrode is on and electrically connected to the second and third semiconductor regions. The first electrode region is electrically connected to the first conductive region, which is on and electrically connected to the second conductive part. The conductive layer is electrically connected to the second electrode and to the first conductive and/or first electrode region.

A semiconductor device includes a semiconductor layer that has a transistor structure including a p type source region, a p type drain region, an n type body region between the p type source region and the p type drain region, and a gate electrode facing the n type body region and a voltage-regulator diode that is disposed at the semiconductor layer and that has an n type portion connected to the p type source region and a p type portion connected to the gate electrode, in which the transistor structure and the voltage-regulator diode are unified into a single-chip configuration.

A SGT MOSFET having ESD diode and a method of manufacturing the same are disclosed. The SGT trench MOSFET according to the present invention, has n+ doped gate shielded electrodes in an N channel device and requires only two poly-silicon layers, making the device can be shrunk with reducing shielded gate width for Rds reduction without increasing switching loss and having dynamic switching instability.

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 semiconductor device including a field-effect transistor having source and drain source regions, first and second gate electrodes and a protective diode connected to the transistor. The first gate electrode is formed over a first gate insulating film in a lower part of a trench. The second gate electrode is formed over a second gate insulating film in an upper part of the trench. The first gate electrode includes a first polysilicon film, and the second gate electrode includes a second polysilicon film, wherein an impurity concentration of the first polysilicon film is lower than an impurity concentration of the second polysilicon film.

A method for manufacturing a power semiconductor device includes forming a drift region in a substrate, forming a trench in the drift region, forming a gate insulating layer in the trench, depositing a conductive material on the substrate, forming a gate electrode in the trench, forming a body region in the substrate, forming a highly doped source region in the body region, forming an insulating layer that covers the gate electrode, etching the insulating layer to open the body region, implanting a dopant into a portion of the body region to form a highly doped body contact region, so that the highly doped source region and the highly doped body contact region are alternately formed in the body region; and forming a source electrode on the highly doped body contact region and the highly doped source region.

A transistor device includes, in a semiconductor body, a drift region, a body region, and a source region separated from the drift region by the body region and connected to a source node. The transistor device further includes a gate electrode dielectrically insulated from the body region by a gate dielectric, and a field electrode structure. The field electrode structure includes: a first field electrode connected to the source node and dielectrically insulated from the drift region by a first field electrode dielectric; a second field electrode dielectrically insulated from the drift region by a second field electrode dielectric; and a coupling circuit connected between the second field electrode and the source node and configured to connect the second field electrode to the source node dependent on a voltage between the source node and the second field electrode.

The present disclosure relates to a semiconductor device, and associated method of manufacture. The semiconductor device includes, MOSFET integrated with a p-n junction, the p-n junction arranged as a clamping diode across a source contact and a drain contact of the MOSFET. The MOSFET defines a first breakdown voltage and the clamping diode defines a second breakdown voltage, with the first breakdown voltage being greater than the second breakdown voltage so that the clamp diode is configured and arranged to receive a low avalanche current and the MOSFET is configured and arranged to receive a high avalanche current.

A semiconductor device includes an active region configured by a first MOS structure region and a second MOS structure region, a gate ring region surrounding a periphery of the active region, a first ring region surrounding a periphery of the gate ring region, a second ring region surrounding a periphery of the first ring region, and a termination region surrounding a periphery of the second ring region. The semiconductor device has first first-electrodes in the first MOS structure region, second first-electrodes in the second MOS structure region, a third first-electrode in the first ring region, and a fourth first-electrode in the second ring region. The third first-electrode has a potential equal to that of the second first-electrodes, and the fourth first-electrode has a potential equal to that of the first first-electrodes.