A radio frequency (RF) device is described. The RF device includes a semiconductor-on-insulator (SOI) substrate having a first-type diffusion region. The RF device also includes a transistor including a source region and a drain region in the first-type diffusion region, a gate region between the source region and the drain region, and a body region. The RF device further includes a second-type diffusion region, comprising a gate overlap region partially overlapped by the gate region to define the body region and a second-type diffusion encroachment region in the source region and adjoining the gate overlap region to form a body terminal region, in which a silicidation layer shorts the body terminal region to the source region.

A semiconductor device and a manufacturing method therefor. The semiconductor device comprises: a semiconductor substrate. A first drift region is formed in the semiconductor substrate. A gate structure is formed on the semiconductor substrate A part of the gate structure covers a part of the first drift region. A first trench is formed in the first drift region, and a drain region is formed in the semiconductor substrate at the bottom of the first trench.

A method of fabricating a semiconductor device is provided. Recesses are formed in a substrate. A first gate dielectric material is formed on the substrate and filled in the recesses. The first gate dielectric material on the substrate between the recesses is at least partially removed to form a trench. A second gate dielectric material is formed in the trench. A gate conductive layer is formed on the second gate dielectric material. Spacers are formed on sidewalls of the gate conductive layer. A portion of the first gate dielectric material is removed. The remaining first gate dielectric material and the second gate dielectric layer form a gate dielectric layer. The gate dielectric layer includes a body part and a first hump part at a first edge of the body part. The first hump part is thicker than the body part. Doped regions are formed in the substrate beside the spacers.

The present disclosure provides a method of manufacturing a semiconductor device includes forming a first gate insulating film on a substrate for a first device, forming a first gate electrode on the first gate insulating film; forming a mask pattern on the first gate electrode to expose opposing end portions of the first gate electrode, wherein a length of the mask pattern is smaller than a length of the first gate electrode; performing ion implantation through the exposed opposing end portions of the first gate electrode using the mask pattern to simultaneously form first and second drift regions in the substrate; forming spacers on sidewalls of the first gate electrode, respectively; and forming a first source region and a first drain region in the first and second drift regions, respectively.

According to an embodiment, a semiconductor device is provided. The device includes: The second region has a greater curvature than the first region. The device includes: an N-type epitaxy layer; a P-well in the N-type epitaxy layer; a drain in the N-type epitaxy layer; a source in the P-well; and a bulk in the P-well and in contact with the source, wherein the bulk has a greater area in the second region than in the first region.

Methods and apparatus for quantum point contacts. In an arrangement, a quantum point contact device includes at least one well region in a portion of a semiconductor substrate and doped to a first conductivity type; a gate structure disposed on a surface of the semiconductor substrate; the gate structure further comprising a quantum point contact formed in a constricted area, the constricted area having a width and a length arranged so that a maximum dimension is less than a predetermined distance equal to about 35 nanometers; a drain/source region in the well region doped to a second conductivity type opposite the first conductivity type; a source/drain region in the well region doped to the second conductivity type; a first and second lightly doped drain region in the at least one well region. Additional methods and apparatus are disclosed.

A method for fabricating isolation device is disclosed. The method includes the steps of: providing a substrate; forming a shallow trench isolation (STI) in the substrate, the STI includes a first STI and a second STI, and the first STI surrounds a first device region and the second STI surrounds a second device region; forming a first doped region between and contact the first STI and the second STI; and forming a first gate structure on the first doped region, the first STI and the second STI.

A high voltage transistor includes a substrate, a well which is disposed within the substrate, a gate disposed on the well, a gate dielectric layer disposed between the well and the gate, two drift regions respectively disposed in the well at two sides of the gate, two source/drain regions respectively disposed within each drift region, wherein a width of the gate dielectric layer is smaller than a width of the source/drain region, and two isolation elements respectively disposed within each drift region

In an LCD driver, in a high voltage resistant MISFET, end portions of a gate electrode run onto electric field relaxing insulation regions. Wires to become source wires or drain wires are formed on an interlayer insulation film of the first layer over the high voltage resistant MISFET. At this moment, when a distance from an interface between a semiconductor substrate and a gate insulation film to an upper portion of the gate electrode is defined as a, and a distance from the upper portion of the gate electrode to an upper portion of the interlayer insulation film on which the wires are formed is defined as b, a relation of a>b is established. In such a high voltage resistant MISFET structured in this manner, the wires are arranged so as not to be overlapped planarly with the gate electrode of the high voltage resistant MISFET.

When an insulated gate bipolar transistor is incorporated in a drive circuit of a flash lamp, so that a light emission pattern of the flash lamp is freely defined, a temperature change pattern of a surface of a semiconductor wafer that receives the emission of flash light can be adjusted. The length of diffusion of impurities can be controlled by rising a surface temperature of the semiconductor wafer from a preheating temperature to a diffusion temperature through emission of flash light and maintaining the surface temperature at the diffusion temperature for a time period not shorter than 1 millisecond and not longer than 10 milliseconds. Subsequently, the impurities can be activated by rising the surface temperature of the semiconductor wafer from the diffusion temperature to an activation temperature.