As disclosed herein, an integrated circuit substrate includes a first region coupled to a signal terminal and includes a guard region coupled via a diode circuit to a supply voltage terminal of the integrated circuit. The first region and the guard region are both of a first conductivity type. A cathode of the diode circuit is connected to the guard region and an anode of the diode circuit is connected to the supply voltage terminal. The first region and the guard region are separated by at least by a second region of the substrate that is of a second conductivity type opposite the first conductivity type.

In a method of manufacturing a semiconductor device, a first-conductivity type implantation region is formed in a semiconductor substrate, and a carbon implantation region is formed at a side boundary region of the first-conductivity type implantation region.

In an insulated trench gate device, polysilicon in the trench is etched below the top surface of the trench, leaving a thin gate oxide layer exposed near the top of the trench. An angled implant is conducted that implants dopants through the exposed gate oxide and into the side of the trench. If the implanted dopants are n-type, this technique may be used to extend an n+ source region to be below the top of the polysilicon in the trench. If the implanted dopants are p-type, the dopants may be used to form a p-MOS device that turns on when the polysilicon is biased with a negative voltage. P-MOS and n-MOS devices can be formed in a single cell using this technique, where turning on the n-MOS device turns on a vertical power switch, and turning on the p-MOS device turns off the power switch.

The present disclosure relates to an integrated chip. The integrated chip includes a source region and a drain region disposed within an upper surface of a substrate. One or more dielectric materials are disposed within a trench defined by sidewalls of the substrate that surround the source region and the drain region. The one or more dielectric materials include one or more interior surfaces defining a recess within the one or more dielectric materials. A gate structure is disposed over the substrate between the source region and the drain region. The gate structure includes a first gate material over the upper surface of the substrate and a second gate material. The second gate material completely fills the recess as viewed along a cross-sectional view.

Some structures and methods to reduce power consumption in devices can be implemented largely by reusing existing bulk CMOS process flows and manufacturing technology, allowing the semiconductor industry as well as the broader electronics industry to avoid a costly and risky switch to alternative technologies. Some of the structures and methods relate to a Deeply Depleted Channel (DDC) design, allowing CMOS based devices to have a reduced σV.sub.T compared to conventional bulk CMOS and can allow the threshold voltage V.sub.T of FETs having dopants in the channel region to be set much more precisely. The DDC design also can have a strong body effect compared to conventional bulk CMOS transistors, which can allow for significant dynamic control of power consumption in DDC transistors. Additional structures, configurations, and methods presented herein can be used alone or in conjunction with the DDC to yield additional and different benefits.

An integrated circuit includes a first semiconductor well contained in a semiconductor substrate and a second semiconductor well contained in the first semiconductor well. A capacitive element for the integrated circuit includes a first electrode and a second electrode, where the first electrode includes at least one vertical conductive structure filling a trench extending vertically into the first semiconductor well. The vertical conductive structure is electrically isolated from the first semiconductor well by a dielectric envelope covering a base and the sides of the trench. The vertical conductive structure penetrates into the second semiconductor well at least at one longitudinal end of the trench. The second electrode includes the first semiconductor well and the second semiconductor well.

Some structures and methods to reduce power consumption in devices can be implemented largely by reusing existing bulk CMOS process flows and manufacturing technology, allowing the semiconductor industry as well as the broader electronics industry to avoid a costly and risky switch to alternative technologies. Some of the structures and methods relate to a Deeply Depleted Channel (DDC) design, allowing CMOS based devices to have a reduced σV.sub.T compared to conventional bulk CMOS and can allow the threshold voltage V.sub.T of FETs having dopants in the channel region to be set much more precisely. The DDC design also can have a strong body effect compared to conventional bulk CMOS transistors, which can allow for significant dynamic control of power consumption in DDC transistors. Additional structures, configurations, and methods presented herein can be used alone or in conjunction with the DDC to yield additional and different benefits.

Electrical overstress protection for high speed applications is provided. In certain embodiments, a method of distributed and customizable electrical overstress protection for a semiconductor die is provided. The method includes configuring a heterogeneous overstress protection array that includes a customizable forward protection circuit electrically connected between a power high pad, a power low pad, and a signal pad and distributed across the semiconductor die, including selecting a number of segmented overstress protection devices from a plurality of available overstress protection devices of the customizable protection circuit. The method also includes choosing a device type of the selected segmented overstress protection devices from amongst two or more different device types providing complementary protection characteristics and protecting a core circuit from electrical overstress using the selected segmented overstress protection devices, the core circuit electrically connected to at least the signal pad, the power high pad, and the power low pad.

The present disclosure provides an integrated circuit that includes a circuit formed on a semiconductor substrate; and a de-cap device formed on the semiconductor substrate and integrated with the circuit. The de-cap device includes a filed-effect transistor (FET) that further includes a source and a drain connected through contact features landing on the source and drain, respectively; a gate stack overlying a channel and interposed between the source and the drain; and a doped feature disposed underlying the channel and connecting to the source and the drain, wherein the doped feature is doped with a dopant of a same type of the source and the drain.

A method of biasing a guard ring structure includes biasing a gate of a MOS transistor to a first bias voltage level, biasing first and second S/D regions of the MOS transistor to a power domain voltage level, biasing a gate of the guard ring structure to a second bias voltage level, and biasing first and second heavily doped regions of the guard ring structure to the power domain voltage level. Each of the first and second S/D regions has a first doping type, each of the first and second heavily doped regions has a second doping type different from the first doping type, and each of the first and second S/D regions and the first and second heavily doped regions is positioned in a substrate region having the second doping type.