A method of making a semiconductor structure, the method including providing a silicon on insulator (SOI) substrate having a first epitaxial layer and a bulk silicon substrate separated by a buried oxide layer. The method further includes performing a local oxidation of silicon (LOCOS) process in a region of the SOI substrate to at least partially oxidize the first epitaxial silicon layer in the region, and locally etching the SOI substrate in the region to create a trench through the buried oxide layer and to the bulk silicon substrate. The method further includes forming a second epitaxial layer on the bulk silicon substrate in the trench, and forming one or more semiconductor devices in the first and second epitaxial layers.

Semiconductor-on-insulator (SOI) field effect transistors (FETs) including body regions having different thicknesses may be formed on an SOI substrate by selectively thinning a region of a top semiconductor layer while preventing thinning of an additional region of the top semiconductor layer. An oxidation process or an etch process may be used to thin the region of the top semiconductor layer, and a patterned oxidation barrier mask or an etch mask may be used to prevent oxidation or etching of the additional portion of the top semiconductor layer. Shallow trench isolation structures may be formed prior to, or after, the selective thinning processing steps. FETs having different depletion region configurations may be formed using the multiple thicknesses of the patterned portions of the top semiconductor layer. For example, partially depleted SOT FETs and fully depleted SOI FETs may be provided.

A high voltage device includes: a semiconductor layer, a well, a bulk region, a gate, a source, and a drain. The bulk region is formed in the semiconductor layer and contacts the well region along a channel direction. A portion of the bulk region is vertically below and in contact with the gate, to provide an inversion region of the high voltage device when the high voltage device is in conductive operation. A portion of the well lies between the bulk region and the drain, to separate the bulk region from the drain. A first concentration peak region of an impurities doping profile of the bulk region is vertically below and in contact with the source. A concentration of a second conductivity type impurities of the first concentration peak region is higher than that of other regions in the bulk region.

A lateral double diffused metal oxide semiconductor (LDMOS) transistor and a semiconductor can reduce the size of the entire power block and can decrease costs by preventing formation of an edge termination region between adjacent device tips or ends along a width direction when the corresponding LDMOS transistor cell has a limited width and the LDMOS transistor is a multi-finger LDMOS transistor.

A method of isolating sections of the channel layer in a SOI workpiece is disclosed. Rather than etching material to create trenches, which are then filled with a dielectric material, ions are implanted into portions of the channel layer to transform these implanted regions from silicon or silicon germanium into an electrically insulating material. These ions may comprise at least one isolating species, such as oxygen, nitrogen, carbon or boron. This eliminates various processes from the fabrication sequence, including an etching process and a deposition process. Advantageously, this approach also results in greater axial strain in the channel layer, since the channel layer is continuous across the workpiece.

The present disclosure relates to a multilayer semiconductor-on-insulator structure, comprising, successively from a rear face toward a front face of the structure: a semiconductor carrier substrate with high electrical resistivity, whose electrical resistivity is between 500 Ω.Math.cm and 30 kΩ.Math.cm, a first electrically insulating layer, an intermediate layer, a second electrically insulating layer, which has a thickness less than that of the first electrically insulating layer, an active semiconductor layer, the multilayer structure comprises: at least one FD-SOI region, in which the intermediate layer is an intermediate first semiconductor layer, at least one RF-SOI region, adjacent to the FD-SOI region, in which the intermediate layer is a third electrically insulating layer, the RF-SOI region comprising at least one radiofrequency component plumb with the third electrically insulating layer.

A semiconductor-on-insulator multilayer structure, comprises: —a stack, called the back stack, of the following layers from a back side to a front side of the structure: a semiconductor carrier substrate the electrical resistivity of which is between 500 Ω.Math.cm and 30 kΩ.Math.cm, a first electrically insulating layer, a first semiconductor layer, —at least one trench isolation that extends through the back stack at least down to the first electrically insulating layer), and that electrically isolates two adjacent regions of the multilayer structure, the multilayer structure being characterized in that it further comprises at least one FD-SOI first region, and at least one RF-SOI second region.

An apparatus includes a first trench formed in a semiconductor layer. The first trench has a first width and a first depth. A second trench is formed in the semiconductor layer. The second trench has a second width and a second depth. The first width is wider than the second width. A buried dielectric layer is disposed between a bottom semiconductor surface of the semiconductor layer and a substrate. The buried dielectric layer contacts a first bottom surface of the first trench. A liner dielectric is formed on the first bottom surface and a first sidewall of the first trench. A first layer is formed on the liner dielectric. A second layer is formed on the first layer and extends to the substrate through an opening formed on the first bottom surface.

A semiconductor device includes a substrate and a semiconductor layer. The substrate includes a planar portion and a plurality of pillars on a periphery of the planar portion. The pillars are shaped as rectangular columns, and corners of two of the pillars at the same side of the planar portion are aligned in a horizontal direction or a direction perpendicular to the horizontal direction. The semiconductor layer is disposed over the planar portion and between the pillars.

The present disclosure relates to semiconductor structures and, more particularly, to a single diffusion break device and methods of manufacture. The structure includes a single diffusion break structure with a fill material between sidewall spacers of the single diffusion break structure and a channel oxidation below the fill material.