A display device includes a pixel including a thin film transistor, and an under layer below the thin film transistor. The thin film transistor includes a first gate electrode, a semiconductor layer and a second gate electrode. The semiconductor layer includes a channel region that overlaps at least one of the first gate electrode and the second gate electrode in a plan view. The channel region curves in a thickness direction of the semiconductor layer. The first gate electrode includes a first edge located on the side of an edge of the channel region in a direction of a channel length. The second gate electrode includes a second edge located on the side of the edge of the channel region. The position of the first edge is different from the position of the second edge in the direction of the channel length.

A semiconductor device includes an oxide semiconductor layer, a gate electrode facing the oxide semiconductor layer, a gate insulating layer between the oxide semiconductor layer and the gate electrode, a first barrier layer below the oxide semiconductor layer, and a second barrier layer above the oxide semiconductor layer, the second barrier layer covering a top surface and side surfaces of the oxide semiconductor layer and being in contact with the first barrier layer in a region around the oxide semiconductor layer.

A transistor having a narrow bandgap semiconductor source/drain region is described. The transistor includes a gate electrode formed on a gate dielectric layer formed on a silicon layer. A pair of source/drain regions are formed on opposite sides of the gate electrode wherein said pair of source/drain regions comprise a narrow bandgap semiconductor film formed in the silicon layer on opposite sides of the gate electrode.

A semiconductor device and methods for manufacturing the same are disclosed. The semiconductor device includes a polymer substrate and an interfacial layer over the polymer substrate. A buried oxide layer resides over the interfacial layer, and a device layer with at least a portion of a field effect device resides over the buried oxide layer. The polymer substrate is molded over the interfacial adhesion layer and has a thermal conductivity greater than 2 watts per meter Kelvin (W/mK) and an electrical resistivity greater than 10.sup.12 Ohm-cm. Methods of manufacture for the semiconductor device include removing a wafer handle to expose a first surface of the buried oxide layer, disposing the interfacial adhesion layer onto the first surface of the buried oxide layer, and molding the polymer substrate onto the interfacial adhesion layer.

Dual gate FD-SOI transistors are used as MOSFET capacitors to replace passive well capacitors in analog microcircuits. Use of the dual gate FD-SOI devices helps to reduce unstable oscillations and improve circuit performance. A thick buried oxide layer within the substrate of an FD-SOI transistor forms a capacitive dielectric that can sustain high operating voltages in the range of 1.2 V-3.3 V, above the transistor threshold voltage. A secondary gate in the FD-SOI transistor is used to create a channel from the back side so that even when the bias voltage on the first gate is small, the effective capacitance remains higher. The capacitance of the buried oxide layer is further utilized as a decoupling capacitor between supply and ground. In one example, a dual gate PMOS FD-SOI transistor is coupled to an operational amplifier and a high voltage output driver to produce a precision-controlled voltage reference generator. In another example, two dual gate PMOS and one dual gate NMOS FD-SOI transistor are coupled to a charge pump, a phase frequency detector, and a current-controlled oscillator to produce a high-performance phase locked loop circuit in which the decoupling capacitor footprint is smaller, in comparison to the conventional usage of passive well capacitance.

An apparatus and method, the apparatus comprising: at least one charged substrate (3); a channel of two dimensional material (5); and at least one floating electrode (7A-C) wherein the floating electrode comprises a first area (10A-C) adjacent the at least one charged substrate, a second area (11A-C) adjacent the channel of two dimensional material and a conductive interconnection (9A-C) between the first area and the second area wherein the first area is larger than the second area and wherein the at least one floating electrode is arranged to control the level of doping within the channel of two dimensional material.

A semiconductor device includes an extremely thin semiconductor-on-insulator substrate (ETSOI) having a base substrate, a thin semiconductor layer and a buried dielectric therebetween. A device channel is formed in the thin semiconductor layer. Source and drain regions are formed at opposing positions relative to the device channel. The source and drain regions include an n-type material deposited on the buried dielectric within a thickness of the thin semiconductor layer. A gate structure is formed over the device channel.

The invention provides methods and devices for fabricating printable semiconductor elements and assembling printable semiconductor elements onto substrate surfaces. Methods, devices and device components of the present invention are capable of generating a wide range of flexible electronic and optoelectronic devices and arrays of devices on substrates comprising polymeric materials. The present invention also provides stretchable semiconductor structures and stretchable electronic devices capable of good performance in stretched configurations.

A semiconductor device includes an SOI substrate having a base substrate material, an active semiconductor layer positioned above the base substrate material and a buried insulating material layer positioned between the base substrate material and the active semiconductor layer. A gate structure is positioned above the active semiconductor layer and a back gate region is positioned in the base substrate material below the gate structure and below the buried insulating material layer. An isolation region electrically insulates the back gate region from the surrounding base substrate material, wherein the isolation region includes a plurality of implanted well regions that laterally contact and laterally enclose the back gate region and an implanted isolation layer that is formed below the back gate region.

A field effect transistor (FET) with raised source/drain region of the device so as to constrain the epitaxial growth of the drain region. The arrangement of the spacer layer is created by depositing a photoresist over the extended drain layer during a photolithographic process.