The present disclosure relates to semiconductor structures and, more particularly, to a symmetric tunnel field effect transistor and methods of manufacture. The structure includes a gate structure including a source region and a drain region both of which comprise a doped VO.sub.2 region.

The present disclosure relates to semiconductor structures and, more particularly, to a symmetric tunnel field effect transistor and methods of manufacture. The structure includes a gate structure including a source region and a drain region both of which comprise a doped VO.sub.2 region.

A power integrated circuit includes a double-diffused metal-oxide-semiconductor (LDMOS) transistor formed in a first portion of the semiconductor layer with a channel being formed in a first body region. The power integrated circuit includes a first deep diffusion region formed in the first deep well under the first body region and in electrical contact with the first body region and a second deep diffusion region formed in the first deep well under the drain drift region and in electrical contact with the first body region. The first deep diffusion region and the second deep diffusion region together form a reduced surface field (RESURF) structure in the LDMOS transistor.

Semiconductor device structures and methods for manufacturing the same are provided. The semiconductor device structure includes a substrate, a first nitride semiconductor layer, a second nitride semiconductor layer, a first transistor and a clamping device. The first nitride semiconductor layer is disposed on the substrate. The second nitride semiconductor layer is disposed on the first nitride semiconductor layer. The first transistor is disposed on the second nitride semiconductor layer. The first transistor includes a first control electrode, a first current electrode and a second current electrode. The clamping device is disposed on the second nitride semiconductor layer and electrically coupled with the first transistor. The clamping device includes a second transistor and a third transistor electrically coupled with the second transistor. The clamping device is electrically coupled with the first current electrode and the second current electrode of the first transistor.

A method of forming a semiconductor device includes a GaN FET with an overvoltage clamping component electrically coupled to a drain node of the GaN FET and coupled in series to a voltage dropping component. The voltage dropping component is electrically coupled to a terminal which provides an off-state bias for the GaN FET. The overvoltage clamping component has a breakdown voltage less than a breakdown voltage of the GaN FET. The voltage dropping component is formed to provide a voltage drop which increases as current from the overvoltage clamping component increases. The semiconductor device is configured to turn on the GaN FET when the voltage drop across the voltage dropping component reaches a threshold value.

An on-resistance of a junction FET is reduced. In a semiconductor device in an embodiment, a gate region of the junction field effect transistor includes a low concentration gate region and a high concentration gate region whose impurity concentration is higher than an impurity concentration of the low concentration gate region, and the high concentration gate region is included in the low concentration gate region.

Both a HEMT and a SBD are formed on a nitride semiconductor substrate. The nitride semiconductor substrate comprises a HEMT gate structure region and an anode electrode region. A first laminated structure is formed at least in the HEMT gate structure region, and includes first to third nitride semiconductor layers. A second laminated structure is formed at least in a part of the anode electrode region, and includes first and second nitride semiconductor layers. The anode electrode contacts the front surface of the second nitride semiconductor layer. At least in a contact region in which the front surface of the second nitride semiconductor layer contacts the anode electrode, the front surface of the second nitride semiconductor layer is finished to be a surface by which the second nitride semiconductor layer forms a Schottky junction with the anode electrode.

A method of forming a double-gated junction field effect transistors (JFET) and a tri-gated metal-oxide-semiconductor field effect transistor (MOSFET) on a common substrate is provided. The double-gated JFET is formed in a first region of a substrate by forming a semiconductor gate electrode contacting sidewall surfaces of a first channel region of a first semiconductor fin and a top surface of a portion of a first fin cap atop the first channel region. The tri-gated MOSFET is formed in a second region of the substrate by forming a metal gate stack contacting a top surface and sidewall surfaces of a second channel region of a second semiconductor fin.

The semiconductor device comprises a semiconductor body with a top side, a main electrode on the top side and a gate electrode. The semiconductor body comprises a drift layer of a first conductivity type, a first base region of a second conductivity type, a second base region of the first conductivity type, a first contact region of the first conductivity type and a second contact region of the second conductivity type. The second base region has a greater doping concentration than the drift layer. The first contact region adjoins the first base region and the top side. The second contact region adjoins the second base region and the top side. The main electrode is in electrical contact with the first and the second contact region. In a first lateral direction, at least a portion of the gate electrode is arranged between the first contact region and the second contact region.

A chamber and surrounding system for the assembly of high yielding, high density, accurately and deterministically placed discrete nano or microparticles or particle arrays are provided, where the positioning of the particles is maintained during a supercritical drying process. The nanoparticle assembly chamber is based upon the dielectrophoretic force generated AC electrodes patterned on a substrate and contacted with electrical feedthroughs, a secondary electrophoretic force generated by a DC electrode opposite the substrate to force particles from the bulk solution near the substrate surface to increase deposition rate, and a fluidic pump to flow solution containing nanoparticles over the substrate surface. The magnitude of the dielectrophoretic forces and electrophoretic force can be adjusted by the geometric parameters, the bias potential applied to the DC bias electrode, and the magnitude of the AC electric field applied to the substrate electrodes.