A capacitor structure is described. A capacitor structure including a substrate; a source/drain region formed in the substrate to form an active area having an active area width; and a plurality of gates formed above the substrate. The source/drain region having a reflection symmetry. Each of the plurality of gates having a gate width. The gate width is configured to be less than said active area width. And, the plurality of gates are formed to have reflection symmetry.

There is provided a structure of a nano memory system. The disclosed unit nano memory cell comprises a single isolated nanoparticle placed on the surface of a semiconductor substrate (301) and an adjacent nano-Schottky contact (303). The nanoparticle works as a storage site where the nano-Schottky contact (303) works as a source or a drain of electrons, in or out of the semiconductor substrate (301), at a relatively small voltage. The electric current through the nano-Schottky contact (303) can be turned on (reading 1) or off (reading 0) by charging or discharging the nanoparticle. Since the electric contact is made by a nano-Scottky contact (303) on the surface and the back contact of the substrate (301), and the charge is stored in a very small nanoparticle, this allows to attain the ultimate device down-scaling. This would also significantly increase the number of nano memory cells on a chip. Moreover, the charging and discharging (writing/erasing), as well as the reading voltages are lower than those needed for CMOS based flash memory cells, due to the small nano-Schottky contact (301) and the small size of the nanoparticle for charge storage.

A micro device structure comprising at least part of an edge of a micro device is covered with a metal-insulator-semiconductor (MIS) structure, wherein the MIS structure comprises a MIS dielectric layer and a MIS gate conductive layer, at least one gate pad provided to the MIS gate conductive layer, and at least one micro device contact extended upwardly on a top surface of the micro device.

Provided are an inverter including a first source and drain, an interlayer insulating film on the first source, a second source on the interlayer insulating film, a second drain on the first drain, a first channel between the first source and drain, a second channel over the first channel between the second source and drain, a gate insulating film covering outer surfaces of the first and second channel, a part of a surface of the first source in the direction to the first drain, a part of a surface of the second source in the direction to the second drain, a part of a surface of the first drain in the direction to the first source, and a part of a surface of the second drain in the direction to the second source, and a gate electrode between the first source and drain and between the second source and drain.

Described is a tunneling field effect transistor (TFET), comprising: a drain region having a first conductivity type; a source region having a second conductivity type opposite of the first conductivity type; a gate region to cause formation of a channel region between the source and drain regions; and a pocket disposed near a junction of the source region, wherein the pocket region formed from a material having lower percentage of one type of atom than percentage of the one type of atom in the source, channel, and drain regions.

A manufacturing method according to an embodiment of this invention is a method of manufacturing a semiconductor device, which has: a first step of forming a first electrode 22 containing Ti or Ta on a top face of a nitride semiconductor layer 18; a second step of forming a second electrode 24 containing Al on a top face of the first electrode 22; a third step of forming a coating metal layer 26 covering at least one of an edge of a top face of the second electrode 24 and a side face of the second electrode 24, having a window 26a exposing the top face of the second electrode 24 in a region separated from the foregoing edge, and containing at least one of Ta, Mo, Pd, Ni, and Ti; and a step of performing a thermal treatment, after the third step.

A manufacturing method according to an embodiment of this invention is a method of manufacturing a semiconductor device, which has: a first step of forming a first electrode 22 containing Ti or Ta on a top face of a nitride semiconductor layer 18; a second step of forming a second electrode 24 containing Al on a top face of the first electrode 22; a third step of forming a coating metal layer 26 covering at least one of an edge of a top face of the second electrode 24 and a side face of the second electrode 24, having a window 26a exposing the top face of the second electrode 24 in a region separated from the foregoing edge, and containing at least one of Ta, Mo, Pd, Ni, and Ti; and a step of performing a thermal treatment, after the third step.

A process for fabricating single or multiple gate field plates using consecutive steps of dielectric material deposition/growth, dielectric material etch and metal evaporation on the surface of a field effect transistors. This fabrication process permits a tight control on the field plate operation since dielectric material deposition/growth is typically a well controllable process. Moreover, the dielectric material deposited on the device surface does not need to be removed from the device intrinsic regions: this essentially enables the realization of field-plated devices without the need of low-damage dielectric material dry/wet etches. Using multiple gate field plates also reduces gate resistance by multiple connections, thus improving performances of large periphery and/or sub-micron gate devices.

A method of manufacturing a semiconductor device includes providing a body of semiconductor material including a substrate and a semiconductor region over the substrate. The method includes providing a spacer over the semiconductor region. The method includes providing a first feature as part of the body of semiconductor material self-aligned to a first side wall of the spacer and providing a second feature as part of the body of semiconductor material self-aligned to a second side wall of the pacer. A portion of the semiconductor region is laterally interposed between the first feature and the second feature, the first feature and the second feature can be doped regions or recesses, and the portion of the semiconductor region laterally interposed between the first feature and the second feature comprises a channel region of a JFET semiconductor device or a JFET region of an insulated gate field effect transistor device.

The present application provides a semiconductor structure and a method for manufacturing the same, which solves a problem that an existing semiconductor structure is difficult to deplete a carrier concentration of a channel under a gate to realize an enhancement mode device. The semiconductor structure includes: a channel layer and a barrier layer superimposed in sequence, wherein a gate region is defined on a surface of the barrier layer; a plurality of trenches formed in the gate region, wherein the plurality of trenches extend into the channel layer; and a P-type semiconductor material filling the plurality of trenches.