A method and apparatus for use in improving linearity sensitivity of MOSFET devices having an accumulated charge sink (ACS) are disclosed. The method and apparatus are adapted to address degradation in second- and third-order intermodulation harmonic distortion at a desired range of operating voltage in devices employing an accumulated charge sink.

A method and apparatus for use in improving linearity sensitivity of MOSFET devices having an accumulated charge sink (ACS) are disclosed. The method and apparatus are adapted to address degradation in second- and third-order intermodulation harmonic distortion at a desired range of operating voltage in devices employing an accumulated charge sink.

A method and apparatus for use in improving linearity sensitivity of MOSFET devices having an accumulated charge sink (ACS) are disclosed. The method and apparatus are adapted to address degradation in second- and third-order intermodulation harmonic distortion at a desired range of operating voltage in devices employing an accumulated charge sink.

A display device includes: a substrate configured to contain an organic material; a first underlying film provided above the substrate; a thin film transistor provided above the first underlying film; a semiconductor film included in the thin film transistor and configured to have a channel region; and an electric field inhibition film provided between the first underlying film and the semiconductor film and configured to overlap the channel region in a plan view. The electric field inhibition film has a higher permittivity than the first underlying film.

A semiconductor device includes insulating substrate; a compound semiconductor layer provided in a first region of a surface of the insulating substrate; and a silicon layer provided in a second region, differing from the first region, of the surface of the insulating substrate. The semiconductor device further includes: a first gate electrode provided on a surface of the compound semiconductor layer; a pair of conductive members provided at positions on the surface of the compound semiconductor layer to sandwich the first gate electrode between the pair of conductive members; a second gate electrode provided on a surface of the silicon layer; and a pair of diffusion layers provided at positions in the silicon layer to sandwich the second gate electrode between the pair of diffusion layers. One of the conductive members is electrically connected to one of the diffusion layers.

A display device includes: a substrate; a semiconductor layer of a transistor, on the substrate; a gate electrode of the transistor on the semiconductor layer; and a conductive layer element corresponding to the transistor. The conductive layer element is both electrically connected to a constant voltage source and contacts the substrate.

An integrated circuit includes a SOI substrate comprising a base substrate, an insulator layer, and a semiconductor device layer. Source and drain regions in the semiconductor device layer are spaced apart by a channel region in the semiconductor device layer. A gate electrode is disposed over the channel region and has a bottom surface that extends below a top surface of the semiconductor device layer. A sidewall spacer structure extends along outer sidewalls of the gate electrode and has a bottom surface that rests on the top surface of the semiconductor device layer. A gate dielectric separates the channel region from the bottom surface of the gate electrode and contacts the bottom surface of the sidewall spacer structure. The channel region beneath the bottom surface of the gate electrode corresponds to the semiconductor device layer and has a thickness of less than 40 angstroms.

A method and apparatus are disclosed for use in improving 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 includes 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.

Semiconductor-on-insulator field effect transistor (FET) integrated circuit (IC) structures and fabrication processes that mitigate or eliminate the problems caused by the secondary parasitic back-channel FET of conventional semiconductor-on-insulator FET IC structures. Embodiments enable full control of the secondary parasitic back-channel FET of semiconductor-on-insulator IC primary FETs. Embodiments include taking partially fabricated ICs made using a process which allows access to the back side of the FET, such as single layer transfer process, and then fabricating a conductive aligned supplemental (CAS) gate structure relative to the insulating layer juxtaposed to a primary FET such that a control voltage applied to the CAS gate can regulate the electrical characteristics of the regions of the primary FET adjacent the insulating layer. The IC structures present as a four or five terminal device: source S, drain D, primary gate G, CAS gate, and, optionally, a body contact.

A method and apparatus for use in improving linearity sensitivity of MOSFET devices having an accumulated charge sink (ACS) are disclosed. The method and apparatus are adapted to address degradation in second- and third-order intermodulation harmonic distortion at a desired range of operating voltage in devices employing an accumulated charge sink.