A transistor includes a quasi-intrinsic region of a first conductivity type that is covered with an insulated gate. The quasi-intrinsic region extends between two first doped regions of a second conductivity type. A main electrode is provided on each of the two first doped regions. A second doped region of a second conductivity type is position in contact with the quasi-intrinsic region, but is electrically and physically separated by a distance from the two first doped regions. A control electrode is provided on the second doped region.

A BiMOS-type transistor includes a gate region, a channel under the gate region, a first channel contact region and a second channel contact region. The first channel contact region is electrically coupled to the gate region to receive a first potential. The second channel contact region is electrically coupled to receive a second potential.

A structure of field-effect transistor includes a silicon layer of a silicon-on-insulator structure. A gate structure layer in a line shape is disposed on the silicon layer, wherein the gate structure layer includes a first region and a second region abutting to the first region. Trench isolation structures in the silicon layer are disposed at two sides of the gate structure layer, corresponding to the second region. The second region of the gate structure layer is disposed on the silicon layer and overlaps with the trench isolation structure. A source region and a drain region are disposed in the silicon layer at the two sides of the gate structure layer, corresponding to the first region. The second region of the gate structure layer includes a conductive-type junction portion.

A structure of field-effect transistor includes a silicon layer of a silicon-on-insulator structure. A gate structure layer in a line shape is disposed on the silicon layer, wherein the gate structure layer includes a first region and a second region abutting to the first region. Trench isolation structures in the silicon layer are disposed at two sides of the gate structure layer, corresponding to the second region. The second region of the gate structure layer is disposed on the silicon layer and overlaps with the trench isolation structure. A source region and a drain region are disposed in the silicon layer at the two sides of the gate structure layer, corresponding to the first region. The second region of the gate structure layer includes a conductive-type junction portion.

A semiconductor structure includes a substrate assembly and a semiconductor device. The semiconductor device is formed on the substrate assembly, and includes a body region, two active regions, and a butted body. The active regions are disposed at two opposite sides of the body region, and both have a first type conductivity. The body region and the active regions together occupy on a surface region of the substrate assembly. The butted body has a second type conductivity different from the first type conductivity, and is located on the surface region of the substrate assembly so as to permit the body region to be tied to one of the active regions through the butted body.

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 semiconductor-on-insulator (SOI) device includes a semiconductor layer situated over a buried oxide layer, the buried oxide layer being situated over a substrate. An SOI transistor is situated in the semiconductor layer and includes a transistor body, gate fingers, source regions, and drain regions. The transistor body has a first conductivity type. The source regions and the drain regions have a second conductivity type opposite to the first conductivity type. The transistor body is electrically tied to at least one source region. An asymmetric halo-implant region having the first conductivity type adjoins the at least one source region. No halo-implant region adjoins the drain regions.

Body-contacted semiconductor structures and methods of forming a body-contacted semiconductor structure. A semiconductor substrate, which contains of a single-crystal semiconductor material, includes a device region and a plurality of body contact regions each comprised of the single-crystal semiconductor material. A polycrystalline layer and polycrystalline regions are formed in the semiconductor substrate. The polycrystalline regions are positioned between the polycrystalline layer and the device region, and the polycrystalline regions have a laterally-spaced arrangement with a gap between each adjacent pair of the polycrystalline regions. One of the plurality of body contact regions is arranged in the gap between each adjacent pair of the polycrystalline regions.

A method and apparatus are disclosed for use in improving the gate oxide reliability of semiconductor-on-insulator (SOI) metal-oxide-silicon field effect transistor (MOSFET) devices using accumulated charge control (ACC) techniques. The method and apparatus are adapted to remove, reduce, or otherwise control accumulated charge in SOI MOSFETs, thereby yielding improvements in FET performance characteristics. In one embodiment, a circuit comprises a MOSFET, operating in an accumulated charge regime, and means for controlling the accumulated charge, operatively coupled to the SOI MOSFET. A first determination is made of the effects of an uncontrolled accumulated charge on time dependent dielectric breakdown (TDDB) of the gate oxide of the SOI MOSFET. A second determination is made of the effects of a controlled accumulated charge on TDDB of the gate oxide of the SOI MOSFET. The SOI MOSFET is adapted to have a selected average time-to-breakdown, responsive to the first and second determinations, and the circuit is operated using techniques for accumulated charge control operatively coupled to the SOI MOSFET. In one embodiment, the accumulated charge control techniques include using an accumulated charge sink operatively coupled to the SOI MOSFET body.

Systems, methods and apparatus are provided for an array of vertically stacked memory cells having horizontally oriented access devices having a first source/drain region and a second source drain region separated by a channel region, and gates opposing the channel region, vertically oriented access lines coupled to the gates and separated from a channel region by a gate dielectric. The memory cells have horizontally oriented storage nodes coupled to the second source/drain region and horizontally oriented digit lines coupled to the first source/drain regions. A vertical body contact is formed in direct electrical contact with a body region of one or more of the horizontally oriented access devices and separate from the first source/drain region and the horizontally oriented digit lines by a dielectric.