The invention provides the guided design approach to optimize the device performance for a best area-efficient layout footprint in a single-leg MOS device that is based on any of the SOI, SOS or SON technologies. The design methodology depends on a new proprietary device architecture that is also being claimed in this patent and that allows the implementations of the design equations of our methodology.

Radio-frequency (RF) devices are fabricated by providing a field-effect transistor (FET) formed over an oxide layer, forming one or more electrical connections to the FET, forming one or more dielectric layers over at least a portion of the electrical connections, electrically coupling an electrical element to the FET via the one or more electrical connections, disposing a handle wafer layer on at least a portion of the one or more dielectric layers, the handle wafer layer being at least partially over the electrical element; and removing at least a portion of the handle wafer layer to form an opening exposing at least a portion of the electrical element.

Systems, methods, and apparatus for an improved body tie construction are described. The improved body tie construction is configured to have a lower resistance body tie exists when the transistor is off (Vg approximately 0 volts). When the transistor is on (Vg>Vt), the resistance to the body tie is much higher, reducing the loss of performance associated with presence of body tie. Space efficient Body tie constructions adapted for cascode configurations are also described.

A substrate contact land for a first MOS transistor is produced in and on an active zone of a substrate of silicon on insulator type using a second MOS transistor without any PN junction that is also provided in the active zone. A contact land on at least one of a source or drain region of the second MOS transistor forms the substrate contact land.

Integrated circuits (ICs) that avoid or mitigate creation of changes in accumulated charge in a silicon-on-insulator (SOI) substrate, particularly an SOI substrate having a trap rich layer. In one embodiment, a FET is configured such that, in a standby mode, the FET is turned OFF while maintaining essentially the same V.sub.DS as during an active mode. In another embodiment, a FET is configured such that, in a standby mode, current flow through the FET is interrupted while maintaining essentially the same V.sub.GS as during the active mode. In another embodiment, a FET is configured such that, in a standby mode, the FET is switched into a very low current state (a trickle current state) that keeps both V.sub.GS and V.sub.DS close to their respective active mode operational voltages. Optionally, S-contacts may be formed in an IC substrate to create protected areas that encompass FETs that are sensitive to accumulated charge effects.

Integrated circuits (ICs) that avoid or mitigate creation of changes in accumulated charge in a silicon-on-insulator (SOI) substrate, particularly an SOI substrate having a trap rich layer. In one embodiment, a FET is configured such that, in a standby mode, the FET is turned OFF while maintaining essentially the same V.sub.DS as during an active mode. In another embodiment, a FET is configured such that, in a standby mode, current flow through the FET is interrupted while maintaining essentially the same V.sub.GS as during the active mode. In another embodiment, a FET is configured such that, in a standby mode, the FET is switched into a very low current state (a trickle current state) that keeps both V.sub.GS and V.sub.DS close to their respective active mode operational voltages. Optionally, S-contacts may be formed in an IC substrate to create protected areas that encompass FETs that are sensitive to accumulated charge effects.

The present disclosure relates to semiconductor structures and, more particularly, to under-body source contact structures and methods of manufacture. The structure includes: a gate structure on a semiconductor layer; a drift region within the semiconductor layer, below the gate structure; a body region within the semiconductor layer, below the gate structure; a contact region within the body region, the contact region being devoid of a silicide contact; and a silicide contact remote from the contact region within the semiconductor layer.

A transistor can include a source and a drain with each implemented in a first type active region, a gate implemented relative to the source and the drain, and a body implemented in the first type active region and substantially covered by the gate. The transistor can further include a body tie implemented in a second type active region and including a connecting portion substantially covered by the gate and engaging the body. The first and second active regions can be dimensioned to provide a gap therebetween on each side of the gate.

A structure for radiofrequency applications includes a high-resistivity support substrate having a front face defining a main plane, a charge-trapping layer disposed on the front face of the support substrate, a first dielectric layer disposed on the charge-trapping layer, an active layer disposed on the first dielectric layer, at least one buried electrode disposed above or in the charge-trapping layer. The buried electrode comprises a conductive layer and a second dielectric layer.

The fabrication of field-effect transistor (FET) devices is described herein where the FET devices include one or more body contacts implemented between source, gate, drain (S/G/D) assemblies to improve the influence of a voltage applied at the body contact on the S/G/D assemblies. The FET devices can include source fingers and drain fingers interleaved with gate fingers. The source and drain fingers of a first S/G/D assembly can be electrically connected to the source and drain fingers of a second S/G/D assembly. The source fingers and the drain fingers can be arranged in alternating rows.