A semiconductor structure includes a substrate, a buried oxide layer formed in the substrate and near a surface of the substrate, a gate dielectric layer formed on the substrate and covering the buried oxide layer, a gate structure formed on the gate dielectric layer and overlapping the buried oxide layer, and a source region and a drain region formed in the substrate and at two sides of the gate structure.

A multilayer composite structure and a method of preparing a multilayer composite structure are provided. The multilayer composite structure comprises a semiconductor handle substrate having a minimum bulk region resistivity of at least about 500 ohm-cm and an isolation region that impedes the transfer of charge carriers along the surface of the handle substrate and reduces parasitic coupling between RF devices.

An apparatus and method of processing a workpiece is disclosed, where a sacrificial capping layer is created on a top surface of a workpiece. That workpiece is then exposed to an ion implantation process, where select species are used to passivate the workpiece. While the implant process is ongoing, radicals and excited species etch the sacrificial capping layer. This reduces the amount of etching that the workpiece experiences. In certain embodiments, the thickness of the sacrificial capping layer is selected based on the total time used for the implant process and the etch rate. The total time used for the implant process may be a function of desired dose, bias voltage, plasma power and other parameters. In some embodiments, the sacrificial capping layer is applied prior to the implant process. In other embodiments, material is added to the sacrificial capping layer during the implant process.

A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell. A first region is in electrical contact with the floating body region. A second region is in electrical contact with the floating body region and is spaced apart from the first region. A gate is positioned between the first and second regions. A buried layer is provided beneath the floating body region. An insulating layer is configured to insulate the memory cell from adjacent memory cells in a first direction. A buried insulating layer is configured to insulate the memory cell from adjacent memory cells in a second direction perpendicular to the first direction.

Semiconductor structures with electrical isolation and methods of forming a semiconductor structure with electrical isolation. A shallow trench isolation region, which contains a dielectric material, is positioned in a semiconductor substrate. A trench extendes through the shallow trench isolation region and to a trench bottom in the semiconductor substrate beneath the shallow trench isolation region. A dielectric layer at least partially fills the trench. A polycrystalline region, which is arranged in the semiconductor substrate, includes a portion that is positioned beneath the trench bottom.

The present disclosure relates to semiconductor structures and, more particularly, to a wafer with localized cavity structures and methods of manufacture. A structure includes a bulk substrate with localized semiconductor on insulator (SOI) regions and bulk device regions, the localized SOI regions includes multiple cavity structures and substrate material of the bulk substrate.

The application provides a method for manufacturing a semiconductor device. The method includes the following operations. A semiconductor substrate is provided, a plurality of separate trenches being formed in the semiconductor substrate. Plasma injection is performed to form a barrier layer between adjacent trenches A respective gate structure is formed in each of the plurality of trenches. A plurality of channel regions are formed in the semiconductor substrate, each of the plurality of trenches corresponding to a respective one of the plurality of channel regions. A source/drain region is formed between each of the plurality of trenches and the barrier layer, the source/drain region being electrically connected to the respective one of the plurality of channel regions, and a conductive type of the barrier layer is opposite to a conductive type of the source/drain region.

A high voltage metal-oxide-semiconductor laterally diffused device (HV LDMOS), and more particularly an insulated gate bipolar junction transistor (IGBT), is disclosed. The device includes a semiconductor substrate, a gate structure formed on the substrate, a source and a drain formed in the substrate on either side of the gate structure, a first doped well formed in the substrate, and a second doped well formed in the first well. The gate, source, second doped well, a portion of the first well, and a portion of the drain structure are surrounded by a deep trench isolation feature and an implanted oxygen layer in the silicon substrate.

This disclosure provides for robust isolation across the SOI structure. In contrast to forming a charge trap layer in specific areas on the structure, a charge trap layer may be built across the insulating/substrate interface. The charge trap layer may be an implantation layer formed throughout and below the insulation layer. Devices built on this SOI structure have reduced cross-talk between the devices. Due to the uniform structure, isolation is robust across the structure and not confined to certain areas. Additionally, deep trench implantation is not required to form the structure, eliminating cost. The semiconductor-on-insulator substrate may include an active silicon layer over an oxide layer. The oxide layer may be over a charge trap layer. The charge trap layer may be over a silicon substrate.

A method of manufacturing a silicon on insulator substrate includes: preparing a semiconductor substrate including a rear side semiconductor layer, an insulating layer, and a front side semiconductor layer, a first surface of the insulating layer being in contact with a surface of the rear side semiconductor layer, and a first surface of the front side semiconductor layer being in contact with a second surface of the insulating layer; forming a high concentration region in which an impurity concentration is increased in the front side semiconductor layer, by injecting impurities into the front side semiconductor layer; heating the semiconductor substrate having the high concentration region; and epitaxially growing an additional semiconductor layer on a second surface of the front side semiconductor layer of the heated semiconductor substrate, the additional semiconductor layer having a lower impurity concentration than the high concentration region.