A semiconductor device includes a gate electrode embedded in each of a plurality of first trenches through an insulating film. The gate electrode includes a first gate electrode electrically connected to a first gate pad and a second gate electrode electrically connected to a second gate pad. A charge period and a discharge period of gate capacitance parasitic on the second gate electrode are shorter than a charge period and a discharge period of gate capacitance parasitic on the first gate electrode, respectively.

A semiconductor device includes an active region, a LOCOS region formed within the active region and that extends vertically above a top surface of the active region, a gate region formed above the top surface of the active region, and a polysilicon resistor having a bottom surface that is offset vertically and physically isolated from a top surface of the LOCOS region. The active region includes a source region laterally disposed from the gate region, a drain region laterally disposed from the gate region, and a drift region laterally disposed between the gate region and the drain region. The polysilicon resistor is formed above the drift region. The active region further includes a first charge balance region formed in the active region below the drift region.

A semiconductor apparatus includes: a gate electrode in a trench and facing a p type base region with a gate insulating film interposed therebetween on a portion of a side wall; a shield electrode in the trench and between the gate electrode and a bottom of the trench; an electric insulating region in the trench, the electric insulating region extending between the gate electrode and the shield electrode, and further extending along the side wall and the bottom of the trench to separate the shield electrode from the side wall and the bottom; a source electrode electrically connected to an n.sup.+ type source region and the shield electrode. The shield electrode has high resistance regions at positions where the high resistance regions face the side walls of the trench, and a low resistance region at a position where the low resistance region is sandwiched between the high resistance regions.

Provided is a semiconductor apparatus includes: a gate electrode disposed inside a trench and opposedly facing a p type base region with a gate insulating film interposed therebetween on a portion of a side wall; a shield electrode disposed inside the trench and positioned between the gate electrode and a bottom of the trench; an electric insulating region disposed inside the trench, the electric insulating region expanding between the gate electrode and the shield electrode, and further expanding along the side wall and the bottom of the trench so as to separate the shield electrode from the side wall and the bottom; a source electrode electrically connected to an n.sup.+ type source region and the shield electrode, wherein the shield electrode has a high resistance region positioned on an n.sup.+ drain region side, and a low resistance region positioned on a gate electrode side.

The present disclosure relates to a semiconductor chip having a level shifter with electro-static discharge (ESD) protection circuit and device applied to multiple power supply lines with high and low power input to protect the level shifter from the static ESD stress. More particularly, the present disclosure relates to a feature to protect a semiconductor device in a level shifter from the ESD stress by using ESD stress blocking region adjacent to a gate electrode of the semiconductor device. The ESD stress blocking region increases a gate resistance of the semiconductor device, which results in reducing the ESD stress applied to the semiconductor device.

A method of fabricating a semiconductor device includes forming a first dielectric layer over a substrate that includes a gate structure, forming a first trench in the first dielectric layer, forming dielectric spacers along sidewalls of the first trench, removing a portion of the dielectric spacers to expose a portion of the sidewalls, forming a first metal feature in the first trench over the another portion of the dielectric spacers and along the exposed portions of the sidewalls of the first trench, forming a second dielectric layer over the first metal feature and the gate structure and forming a second trench through the second dielectric layer to expose a portion of the first metal feature and a third trench through the second dielectric layer and the first dielectric layer to expose a portion of the gate structure in the same etching process.

The present examples relate to a semiconductor chip having a level shifter with an electrostatic discharge (ESD) protection circuit and a device applying to multiple power supply lines with high and low power inputs to protect the level shifter from the static ESD stress. More particularly, the present examples relate to using a feature to protect a semiconductor device in a level shifter from the ESD stress by using ESD stress blocking region adjacent to a gate electrode of the semiconductor device. The ESD stress blocking region increases a gate resistance of the semiconductor device, which results in reducing the ESD stress applied to the semiconductor device itself.

A semiconductor device includes a substrate having an active pattern thereon, a gate electrode intersecting the active pattern, and a spacer on a sidewall of the gate electrode. The gate electrode includes a first metal pattern adjacent to the active pattern. The first metal pattern has a first portion parallel to the sidewall and a second portion parallel to the substrate. A top surface of the first portion has a descent in a direction from the spacer towards the second portion.

Described herein are semiconductor devices and methods of forming the same. In some aspects, methods of forming a semiconductor device includes forming a gate stack having a self-aligning cap and a gate metal on a substrate, depositing a resist mask onto the semiconductor device, and patterning the resist mask such that the gate stack is exposed. Additionally, methods include removing the self-aligning cap and the gate metal from the exposed gate stack, depositing a resistor metal on the semiconductor device such that a metal resistor is formed within the exposed gate stack, and forming a bar contact and contact via above the metal resistor.

Described herein are semiconductor devices and methods of forming the same. In some aspects, methods of forming a semiconductor device includes forming a gate stack having a self-aligning cap and a gate metal on a substrate, depositing a resist mask onto the semiconductor device, and patterning the resist mask such that the gate stack is exposed. Additionally, methods include removing the self-aligning cap and the gate metal from the exposed gate stack, depositing a resistor metal on the semiconductor device such that a metal resistor is formed within the exposed gate stack, and forming a bar contact and contact via above the metal resistor.