Some embodiments of the present disclosure provide a semiconductor device including a substrate and a gate structure on the substrate. A first well region of a first conductivity type is in the substrate, close to a first sidewall of the gate structure. A second well region of a second conductivity type is also in the substrate close to the second sidewall of the gate structure. A conductive region is disposed in the second well region. The conductive region can be an epitaxy region. A chemical composition inside the second well region between the conductive region and the gate structure is essentially homogeneous as a chemical composition throughout the second well region.

A semiconductor device includes a semiconductor substrate having a first side. At least a first doping region is formed in the semiconductor substrate. The first doping region has a laterally varying doping dosage and/or a laterally varying implantation depth.

A semiconductor device, including a substrate; a first conductive type well and a second conductive type body region at an upper portion of the substrate; a field plate on the first conductive type well, the field plate including a semiconductor material or an insulative nitride; and a gate electrode extending in a lateral direction on the substrate from a lateral portion of the second conductive type body region to a lateral portion of the first conductive type well, the gate electrode overlapping the field plate.

A resistive random access memory (RRAM) structure includes a resistive memory element formed on a semiconductor substrate and designed for data storage. The resistive element includes a resistive material layer. The resistive element further includes first and second electrodes interposed by the resistive material layer. The resistive element further includes a field effect transistor (FET) formed on the semiconductor substrate and coupled with the resistive memory element, wherein the FET includes asymmetric source and drain, the drain having a higher doping concentration than the source. The resistive memory element is coupled with the drain.

A method for detecting the presence and location of defects over a substrate is disclosed. In an embodiment, the method may include: forming a semiconductor material in a plurality of openings in a reference wafer using an epitaxial growth process; performing one or more measurements on the reference wafer to obtain a baseline signal; forming a plurality of gate stacks and stressor regions in a plurality of substrates; after forming the plurality of gate stacks, forming the semiconductor material in a plurality of openings in a batch wafer; performing the one or more measurements on the batch wafer to obtain a batch signal; comparing the batch signal to the baseline signal; and determining whether a defect in present in the plurality of substrates based on the comparison.

The present disclosure provides a method for forming a semiconductor device, including: providing a semiconductor substrate; forming a well region and a drift region in the semiconductor substrate; and forming one or more counter-doped regions in the drift region, the one or more counter-doped regions being aligned along a direction vertical to the semiconductor substrate to divide the drift region into a plurality of parts. The semiconductor fabrication method also includes: forming a gate structure on the semiconductor substrate, the gate structure covering a portion of the well region and a portion of the drift region; and forming a source electrode in the well region on one side of the gate structure and a drain electrode in the drift region on another side of the gate structure.

A semiconductor device is provided. The semiconductor device includes a semiconductor substrate, a P-well and an N-well disposed in the semiconductor substrate, a source disposed in the N-well and a drain disposed in the P-well, a shallow trench isolation (STI) structure disposed in the P-well, a gate structure disposed on the semiconductor substrate, wherein a portion of the gate structure extends into the semiconductor substrate and is disposed in a location corresponding to the STI structure.

A semiconductor device includes a plurality of epitaxial layers stacked over a supportive substrate, a first buried impurity region formed to share the supportive substrate with a lowermost epitaxial layer among the multiple epitaxial layers, one or more second buried impurity regions formed to be coupled with the first buried impurity region and share an N.sup.th epitaxial layer and an (N+1).sup.th epitaxial layer among the multiple epitaxial layers, where N is a natural number, a body region formed in an uppermost epitaxial layer among the multiple epitaxial layers and a deep well formed in the uppermost epitaxial layer to surround the body region and to be coupled with the second buried impurity regions that share the uppermost epitaxial layer.

A semiconductor device is provided. The device includes a substrate having a first conductivity type. The device further includes a drain region, a source region, and a well region disposed in the substrate. The well region is disposed between the drain region and the source region and having a second conductivity type opposite to the first conductivity type. The device further includes a plurality of doped regions disposed within the well region. The doped regions are vertically and horizontally offset from each other. Each of the doped regions includes a lower portion having the first conductivity type, and an upper portion stacked on the lower region and having the second conductivity type.

A semiconductor device configured with one or more integrated breakdown protection diodes in non-isolated power transistor devices and electronic apparatus, and methods for fabricating the devices.