A semiconductor structure includes a semiconductor substrate having a first portion and a second portion. A first Fin field-effect transistor (FinFET) is formed over the first portion of the semiconductor substrate, wherein the first FinFET includes a first fin having a first fin height. A second FinFET is formed over the second portion of the semiconductor substrate, wherein the second FinFET includes a second fin having a second fin height different from the first fin height. A top surface of the first fin is substantially level with a top surface of the second fin. A punch-through stopper is underlying and adjoining the first FinFET, wherein the punch-through stopper isolates the first fin from the first portion of the semiconductor substrate.

A semiconductor device including a substrate having an active region and a field-plate region therein is disclosed. At least one trench-gate structure is in the substrate. The field-plate region is at a first side of the trench-gate structure. At least one source doped region is in the substrate at a second side opposite to the first side of the trench-gate structure. The source doped region adjoins the sidewall of the trench-gate structure. A drain doped region is in the substrate corresponding to the active region. The field-plate region is between the drain doped region and the trench-gate structure. An extending direction of length of the trench-gate structure is perpendicular to that of the drain doped region as viewed from a top-view perspective.

An LDMOS transistor can include: a field oxide layer structure adjacent to a drain region; and at least one drain oxide layer structure adjacent to the field oxide layer structure along a lateral direction, where a thickness of the drain oxide layer structure is less than a thickness of the field oxide layer, and at least one of a length of the field oxide layer structure and a length of the drain oxide layer structure is adjusted to improve a breakdown voltage performance of the LDMOS transistor.

A method for making a deep trench isolation of a CIS device includes: growing a first epitaxial layer on a substrate; forming a hard mask layer on the first epitaxial layer; performing photolithography and etching processes to form deep trenches arranged longitudinally and transversely in the first epitaxial layer; forming a second epitaxial layer in the deep trenches; performing a thermal oxidation process to form a first oxide layer on the surface of the second epitaxial layer; completely filling the deep trenches with polysilicon; performing a back-etching process to expose sidewalls of the first oxide layer in the deep trenches; forming a second oxide layer on the top of the polysilicon; removing the hard mask layer and the first oxide layer above the second oxide layer; rapidly growing a third epitaxial layer; and performing a CMP process to form a deep trench isolation on the substrate.

A method for manufacturing a device may include providing an ultra-high voltage (UHV) component that includes a source region and a drain region, and forming an oxide layer on a top surface of the UHV component. The method may include connecting a low voltage terminal to the source region of the UHV component, and connecting a high voltage terminal to the drain region of the UHV component. The method may include forming a shielding structure on a surface of the oxide layer provided above the drain region of the UHV component, forming a high voltage interconnection that connects to the shielding structure and to the high voltage terminal, and forming a metal routing that connects the shielding structure and the low voltage terminal.

A method for forming a semiconductor device structure is provided. The method includes forming a semiconductor strip structure over a semiconductor substrate. The semiconductor strip structure has a first doped region and a spacing region connected to the first doped region, and the spacing region is an undoped region. The method includes performing an implantation process over the first doped region and the spacing region to convert a first upper portion of the first doped region and a second upper portion of the spacing region into a continuous disorder region. The method includes forming a metal-semiconductor compound layer over the semiconductor strip structure to continuously cover the first doped region and the spacing region after the implantation process.

A semiconductor-on-insulator (SOI) substrate includes a handle substrate, a charge-trapping layer located over the handle substrate and including nitrogen-doped polysilicon, an insulating layer located over the charge-trapping layer, and a semiconductor material layer located over the insulating layer. The nitrogen atoms in the charge-trapping layer suppress grain growth during anneal processes used to form the SOI substrate and during subsequent high temperature processes used to form semiconductor devices on the semiconductor material layer. Reduction in grain growth reduces distortion of the SOI substrate, and facilitates overlay of lithographic patterns during fabrication of the semiconductor devices. The charge-trapping layer suppresses formation of a parasitic surface conduction layer, and reduces capacitive coupling of the semiconductor devices with the handle substrate during high frequency operation such as operations in gigahertz range.

Embodiments of the invention are directed to a method of performing fabrication operations to form a transistor, wherein the fabrication operations include forming a source or drain (S/D) region having an S/D formation assistance region at least partially within a portion of a substrate. An S/D isolation region is formed around sidewalls and a bottom surface of the S/D formation assistance region and configured to electrically isolate the S/D formation assistance region from the substrate.

Described examples include integrated circuits, drain extended transistors and fabrication methods in which a silicide block material or other protection layer is formed on a field oxide structure above a drift region to protect the field oxide structure from damage during deglaze processing. Further described examples include a shallow trench isolation (STI) structure that laterally surrounds an active region of a semiconductor substrate, where the STI structure is laterally spaced from the oxide structure, and is formed under gate contacts of the transistor.

A semiconductor device includes a semiconductor substrate having a source region and a drain region, a first insulator between the source region and the drain region, a gate electrode having a first end on a side thereof closer to the source region than the drain region on a portion of the semiconductor substrate that is not covered with the first insulator, and having a second end on the first insulator closer to the drain region than the source region, and a second insulator that is continuous with the second end of the gate electrode and having a portion which is on the first insulator where the first insulator is not covered with the gate electrode, is on an end of the drain region, and is in contact with the gate electrode, the first insulator, and the drain region.