Integrated circuits are presented having high voltage IGBTs with integral emitter shorts and fabrication processes using wafer bonding or grown epitaxial silicon for controlled drift region thickness and fast switching speed.

A semiconductor device includes a first gate trench and a second gate trench in a first main surface of a semiconductor substrate. A mesa is arranged between the first gate trench and the second gate trench. The mesa separates the first gate trench from the second gate trench. Each of the first and second gate trenches includes first sections extending in a first direction and second sections connecting adjacent ones of the first sections. The second sections of the first gate trench are disposed opposite to the second sections of the second gate trench with respect to a plane perpendicular to the first direction.

Provided is a method of forming fine patterns, which is capable of easily forming a plurality of patterns repeatedly with a fine pitch when forming patterns necessary for manufacturing a highly integrated semiconductor device exceeding a resolution limit of a photolithography process.

This disclosure relates to a method for dissolving a silicon dioxide layer in a structure, including, from the back surface thereof to the front surface thereof, a supporting substrate, the silicon dioxide layer and a semiconductor layer, the dissolution method being implemented in a furnace in which structures are supported on a support, the dissolution method resulting in the diffusion of oxygen atoms included in the silicon dioxide layer through the semiconductor layer and generating volatile products, and the furnace including traps suitable for reacting with the volatile products, so as to reduce the concentration gradient of the volatile products parallel to the front surface of at least one structure.

A method of fabricating a bipolar transistor device includes performing a first plurality of implantation procedures to implant dopant of a first conductivity type to form emitter and collector regions laterally spaced from one another in a semiconductor substrate, and performing a second plurality of implantation procedures to implant dopant of a second conductivity type in the semiconductor substrate to form a composite base region. The composite base region includes a base contact region, a buried region through which a buried conduction path between the emitter and collector regions is formed during operation, and a base link region electrically connecting the base contact region and the buried region. The base link region has a dopant concentration level higher than the buried region and is disposed laterally between the emitter and collector regions.

Disclosed are methods that employ a mask with openings arranged in a pattern of elongated trenches and holes of varying widths to achieve a linearly graded conductivity level. These methods can be used to form a lateral double-diffused metal oxide semiconductor field effect transistor (LDMOSFET) with a drain drift region having an appropriate type conductivity at a level that increases essentially linearly from the body region to the drain region. Furthermore, these methods also provide for improve manufacturability in that multiple instances of this same pattern can be used during a single dopant implant process to implant a first dopant with a first type (e.g., N-type) conductivity into the drain drift regions of both first and second type LDMOSFETs (e.g., N and P-type LDMOSFETs, respectively). In this case, the drain drift region of a second type LDMOSFET can subsequently be uniformly counter-doped. Also disclosed are the resulting semiconductor structures.

A chip part includes a substrate, an element formed on the substrate, and an electrode formed on the substrate. A recess and/or projection expressing information related to the element is formed at a peripheral edge portion of the substrate.

It is prevented that when a predetermined number of semiconductor chips having transistors are manufactured from one semiconductor wafer, manufacturing cost of a semiconductor device is increased due to excess semiconductor chips manufactured from the semiconductor wafer. A first bipolar transistor including a first emitter region having a first area is formed in a first chip formation region in an exposure region that can be exposed by one exposure step, and a second bipolar transistor including a second emitter region having a second area different from the first area is formed in a second chip formation region in the exposure region.

A method of fabricating a device includes providing a process substrate on a carrier substrate, where the process substrate has a rectangular shape with a pair of long sides and a pair of short sides, providing a device on the process substrate, and continuously peeling the process substrate from the carrier substrate along a curve passing through a starting point which is one of vertices the process substrate, where the curve substantially perpendicularly passes through one of the short sides spaced apart from the starting point.

Design and fabrication methods to reduce the effect of edge-placement errors in the cut-hole patterning process are invented using selective etching and dual-material self-aligned multiple patterning processes. The invented methods consist of a series of processing steps to decompose the original cut-hole mask into multiple separate masks, pattern the cut holes on the resist to expose certain targeted lines, and selectively etch the exposed targeted lines (formed by dual-material self-aligned multiple patterning processes) without attacking the non-target lines. This invention provides production-worthy methods for the semiconductor industry to continue IC scaling down to sub-10 nm half pitch.