A microelectronic device including a substrate having a semiconductor material containing a laterally diffused metal oxide semiconductor (LDMOS) transistor, including a body region of a first conductivity type and a drift region of an opposite conductivity type. A gate dielectric layer over a channel region of the body, the gate dielectric extending over a junction between a body region and the drift region with a gate electrode on the gate dielectric and a drain contact in the drain drift region, having the second conductivity type. A field relief dielectric layer on the drain drift region extending from the drain region to the gate dielectric, having a thickness greater than the gate dielectric layer. A silicide-blocking layer extends from the drain region toward the gate, providing an unsilicided portion of the drift region at the substrate top surface between the drain region and the gate.

A method of manufacturing an integrated circuit includes forming first and second false collector regions of a first conductivity type adjacent to a surface of an epitaxial layer of semiconductor material. The first false collector region is located laterally on a first side of a base region. The base region is formed within the epitaxial layer and has a second conductivity type. The second false collector region is located laterally on a second side of the base region. The second side is opposite the first side of the base region. The base region is a base of a parasitic bipolar junction in an isolation region of an active semiconductor device.

An integrated circuit structure includes a semiconductor substrate, a first source/drain feature, a second source/drain feature, a gate dielectric layer, a gate electrode, a field plate electrode, and a dielectric layer. The semiconductor substrate has a well region and a drift region therein. The first source/drain feature is in the well region. The second source/drain feature is in the semiconductor substrate. The drift region is between the well region and the second source/drain feature. The gate dielectric layer is over the well region and the drift region. The gate electrode is over the gate dielectric layer and vertically overlapping the well region. The field plate electrode is over the gate dielectric layer and vertically overlapping the drift region. The dielectric layer is between the gate electrode and the field plate electrode. A top surface of the gate electrode is free of the dielectric layer.

A semiconductor device includes a semiconductor substrate comprising a P-type lightly doped semiconductor layer; an undoped silicon layer formed on the P-type lightly doped semiconductor layer; a first deep trench isolation and a second deep trench isolation formed from an upper surface of the semiconductor substrate to the undoped silicon layer and filled with insulating films; and a first N-type highly doped buried layer formed on the undoped silicon layer, and disposed between the first deep trench isolation and the second deep trench isolation, wherein the undoped silicon layer surrounds bottoms of the first and second deep trench isolations, and has a thickness greater than a thickness of the first N-type highly doped buried layer.

The present disclosure provides a semiconductor device capable of reducing wiring resistance by using a stripe wire. The semiconductor device includes: a source pad electrode formed on a second interlayer insulating layer; a plurality of source extraction electrodes extracted in a first direction from the source pad electrode; a drain pad electrode formed on the second interlayer insulating layer; and a plurality of drain extraction electrodes extracted in the first direction from the drain pad electrode. The source pad electrode and the plurality of source extraction electrodes are electrically connected to a plurality of source wires of stripe wire covered by the second interlayer insulating layer. The drain pad electrode and the plurality of drain extraction electrodes are electrically connected to a plurality of drain wires of the stripe wire. The plurality of drain extraction electrodes are engaged with the plurality of source extraction electrodes.

A SiC integrated circuit structure which allows multiple power MOSFETs or LDMOSs to exist in the same piece of semiconductor substrate and still function as individual devices which form the components of a given circuit architecture, for example, and not by limitation, in a half-bridge module. In one example, a deep isolation trench is etched into the silicon carbide substrate surrounding each individual LDMOS device. The trench is filled with an insulating material. The depth of the trench may be deeper than the thickness of an epitaxial layer to ensure electrical isolation between the individual epitaxial layer regions housing the individual LDMOSs. The width of the trench may be selected to withstand the potential difference between the bias levels of the body regions of neighboring power LDMOS devices.

A semiconductor device includes a semiconductor substrate including a corrugated surface. A body has a first conductivity type and includes a portion extending continuously along the corrugated surface. A gate dielectric layer is on the body and extends continuously along the corrugated surface. A gate is on the gate dielectric layer, the gate extending continuously along the corrugated surface. A corrugated conformal drift region has a second conductivity type opposite from the first conductivity type, and is on and conformal with the corrugated surface of the semiconductor substrate, and extends continuously along the corrugated surface. A source has the second conductivity type and includes a portion extending continuously along the corrugated surface, the source being in contact with the body. A drain contact region electrically coupled to the drift region and having the second conductivity type.

An apparatus includes a first lateral diffusion field effect transistor (LDFET) having a first threshold voltage and that includes a first gate electrode, a first drain contact, a first source contact, and a first electrically conductive shield plate separated from the first gate electrode and the first source contact by a first interlayer dielectric. A second LDFET of the apparatus has a second threshold voltage and includes a second gate electrode, a second drain contact, and a second source contact. The second source contact is electrically connected to the first source contact of the first LDFET. A control circuit of the apparatus is electrically coupled to the first electrically conductive shield plate and is configured to apply to the first electrically conductive shield plate a first gate bias voltage of a first level to set the first threshold voltage of the first LDFET to a first desired threshold voltage.

A semiconductor device includes a semiconductor substrate comprising a P-type lightly doped semiconductor layer; an undoped silicon layer formed on the P-type lightly doped semiconductor layer; a first deep trench isolation and a second deep trench isolation formed from an upper surface of the semiconductor substrate to the undoped silicon layer and filled with insulating films; and a first N-type highly doped buried layer formed on the undoped silicon layer, and disposed between the first deep trench isolation and the second deep trench isolation, wherein the undoped silicon layer surrounds bottoms of the first and second deep trench isolations, and has a thickness greater than a thickness of the first N-type highly doped buried layer.

A semiconductor device includes a chip that has a first main surface on one side and a second main surface on another side, a pn-junction portion that is formed in an interior of the chip such as to extend along the first main surface, a device region that is provided in the first main surface, a first trench structure that is formed in the first main surface such as to penetrate through the pn-junction portion and demarcates the device region in the first main surface, and a second trench structure that is formed in the first main surface such as to penetrate through the pn-junction portion and demarcates the device region in a region further to the device region side than the first trench structure.