A semiconductor device includes a power device and a temperature detection diode. The semiconductor device has a device structure configured to insulate between a power lien of the power device and the temperature detection diode.

An electrostatic discharge protection structure includes: substrate of a first type of conductivity, well region of a second type of conductivity, substrate contact region in the substrate and of the first type of conductivity, well contact region in the well region and of the second type of conductivity, substrate counter-doped region between the substrate contact region and the well contact region and of the second type of conductivity, well counter-doped region between the substrate contact region and the well contact region and of the first type of conductivity, communication region at a lateral junction between the substrate and the well region, first isolation region between the substrate counter-doped region and the communication region, second isolation region between the well counter-doped region and the communication region, oxide layer having one end on the first isolation region and another end on the substrate, and field plate structure on the oxide layer.

Examples of the present technology include semiconductor processing methods that may include generating a plasma from a deposition precursor in a processing region of a semiconductor processing chamber. The plasma may be generated at a delivered power within a first period of time when plasma power is delivered from a power source operating at a first duty cycle. The methods may further include transitioning the power source from the first duty cycle to a second duty cycle after the first period of time. A layer may be deposited on a substrate in the processing region of the semiconductor processing chamber from the generated plasma. The layer, as deposited, may be characterized by a thickness of 50 Å or less. Exemplary deposition precursors may include one or more silicon-containing precursors, and an exemplary layer deposited on the substrate may include an amorphous silicon layer.

Methods for depositing a metal film on a doped amorphous silicon layer as a nucleation layer and/or a glue layer on a substrate. Some embodiments further comprise the incorporation of a glue layer to increase the ability of the doped amorphous silicon layer and metal layer to stick to the substrate.

Disclosed is a method of manufacturing a semiconductor device, including: forming a stacked structure including first material layers and second material layers alternately stacked on each other; forming a pillar passing through the stacked structure, the pillar including a protruding portion protruding above an uppermost surface of the stacked structure; forming a conductive layer surrounding the protruding portion of the pillar; and forming a conductive pattern in contact with the protruding portion of the pillar by oxidizing a surface of the conductive layer.

The disclosure includes forming a SiGe region on two adjacent fin structures and a SiP region on the fin structures adjacent to the SiGe region; forming SDB trenches; forming SiN plugs over the SDB trenches to make top-sealed hollow SDB trenches. The process for forming SDB trenches adds no additional cost, and the process is compatible with existing process flow. The SiN plugs are configured to seal the SDB trenches from top, such that the SDB trenches are filled with air and do not need to be thermally annealed. The advantage includes low fin loss in the annealing oxidation process and better controlled uniformity of the SDB trenches. Air in the SDB trenches reduces the parasitic capacitance of adjacent contacts, therefore and it is conducive to improving the device speed.

Embodiments of the present disclosure relate to processes for filling trenches. The process includes depositing a first amorphous silicon layer on a surface of a layer and a second amorphous silicon layer in a portion of a trench formed in the layer, and portions of side walls of the trench are exposed. The first amorphous silicon layer is removed. The process further includes depositing a third amorphous silicon layer on the surface of the layer and a fourth amorphous silicon layer on the second amorphous silicon layer. The third amorphous silicon layer is removed. The deposition/removal cyclic processes may be repeated until the trench is filled with amorphous silicon layers. The amorphous silicon layers form a seamless amorphous silicon gap fill in the trench since the amorphous silicon layers are formed from bottom up.

A method of processing a semiconductor device includes: creating first and second recesses in a surface of a semiconductor body; creating an insulation layer that forms first and second wells each having a common lateral extension range with the portion of the insulation layer located between the recesses; filling the wells with a plug material having the respective common lateral extension range with the insulation layer; removing a middle portion of the insulation layer located between the recesses; filling, with a filling material, a third recess created in a region where the middle portion has been removed and at least a portion of the space located between the wells; creating a first common surface of the insulation layer, the plug material, and the filling material; removing the plug material from the second well; and creating a second insulation layer that covers a side wall of the second recess.

An integrated circuit with a matched transistor pair with a matching resistance heater coupled to each transistor of the matched transistor pair. A method for forming a matching resistance heater. A method for operating an SOI integrated circuit containing a matched transistor pair with a matching resistance heater coupled to each transistor of the matched transistor pair.

Stacks of electrically resistive materials and related apparatuses, electrical systems, and methods are disclosed. An apparatus includes one or more resistor devices including a substrate, first and second electrically resistive materials, and an electrically insulating material between the first and second electrically resistive materials. The substrate includes a semiconductor material. A stepped trench is defined in the substrate by sidewalls and horizontal surfaces of the semiconductor material. The first electrically resistive material and the second electrically resistive material are within the stepped trench. A method of manufacturing a resistor device includes forming a stepped trench in the substrate, forming an etch stop material within the stepped trench, disposing an electrically resistive material within the stepped trench, disposing an electrically insulating material on the electrically resistive material, and repeating the disposing the electrically resistive material and the disposing the electrically insulating material operations a predetermined number of times.