An electronic device can include a channel layer, a first carrier supply layer, a gate electrode of a HEMT, and a drain electrode of the HEMT. The HEMT can have a 2DEG along an interface between the channel and first carrier supply layers. In an aspect, the 2DEG can have a highest density that is the highest at a point between the drain and gate electrodes. In another aspect, the HEMT can further comprise first and second carrier supply layers, wherein the first carrier supply layer is disposed between the channel and second carrier supply layers. The second carrier supply layer be thicker at a location between the drain and gate electrodes. In a further aspect, a process of forming an electronic device can include the HEMT. In a particular embodiment, first and second carrier supply layers can be epitaxially grown from an underlying layer.

Structures for laterally-diffused metal-oxide-semiconductor devices and drain-extended metal-oxide-semiconductor devices, as well as methods of forming laterally-diffused metal-oxide-semiconductor devices and drain-extended metal-oxide-semiconductor devices. A gate electrode is arranged to extend about a semiconductor fin projecting from a substrate. A drain region is arranged in the substrate, and a source region is coupled with the semiconductor fin. The source region is arranged over the semiconductor fin. A drift region is arranged in the substrate between the drain region and the semiconductor fin. The drain region, source region, and drift region have a given conductivity type. The drift region has a lower electrical conductivity than the drain region.

For example, an Electrostatically Formed Nanowire (EFN) may include a source region; at least one drain region; a wire region configured to drive a current between the source and drain regions via a conductive channel; a first lateral-gate area extending along a first surface of the wire region between the source and drain regions; a second lateral-gate area extending along a second surface of the wire region between the source and drain regions; and a sensing area in opening in a backside of a silicon substrate under the wire region and the first and second lateral-gate areas, the sensing area configured to, in reaction to a predefined substance, cause a change in a conductivity of the conductive channel.

A semiconductor structure has a substrate including silicon and a layer of relaxed buffer material on the substrate with a thickness no greater than 300 nm. The buffer material comprises silicon and germanium with a germanium concentration from 20 to 45 atomic percent. A source and a drain are on top of the buffer material. A body extends between the source and drain, where the body is monocrystalline semiconductor material comprising silicon and germanium with a germanium concentration of at least 30 atomic percent. A gate structure is wrapped around the body.

Low-power multi-stage amplifiers are provided for capacitive reading of low-amplitude and low-frequency signals. An exemplary multi-stage amplifier comprises a plurality of amplification stages, wherein each of the amplification stages comprises an amplifying transistor and an active load, wherein substantially all of the amplification stages have one or more of an increasing DC bias level and a decreasing DC bias level relative to a prior stage, and wherein an output of a given one of the amplification stages is directly applied as an input to a subsequent one of the amplification stages.

A process of forming a field effect transistor (FET) and a FET are disclosed. The process includes steps of forming a nitride semiconductor layer on a substrate; selectively growing an n.sup.+-region made of oxide semiconductor material on the nitride semiconductor layer and subsequently depositing oxide film on the n.sup.+-region; rinsing the oxide film with an acidic solution; forming an opening in the oxide film to expose the oxide semiconductor layer therein; and depositing a metal within the opening such that the metal is in direct contact with the n.sup.+-region.

The present disclosure relates to semiconductor structures and, more particularly, to sealed cavity structures having a non-planar surface features and methods of manufacture. The structure includes a cavity formed in a substrate material. The cavity is covered with epitaxial material that has a non-planar surface topography which imparts a stress component on a transistor.

A semiconductor structure that occupies only one areal device area is provided that includes a charge storage region sandwiched between a pFET nanosheet device and an nFET nanosheet device. The charge storage region is an epitaxial oxide nanosheet that is lattice matched to an underlying first silicon channel material nanosheet and an overlying second silicon channel material nanosheet. The semiconductor structure can be used as an EPROM device.

Provided herein is a semiconductor device and a method of manufacturing the same. The semiconductor device has improved erase characteristics by using a select gate enclosing a portion a first semiconductor region overlapping a second semiconductor region. The first semiconductor region and the second semiconductor region are formed of different semiconductor materials.

A method includes providing a semiconductor body including a plurality of two-dimensional charge carrier gas channels, forming a gate fin by forming a pair of gate trenches in an upper surface of the semiconductor body, the pair of gate trenches exposing each one of two-dimensional charge carrier gas channels, providing source and drain contacts that are electrically connected to each one of the plurality of two-dimensional charge carrier gas channels, providing a gate structure that is configured to control a conductive connection between the source and drain contacts, wherein providing the gate structure includes forming a layer of doped type III-nitride semiconductor material that covers the gate fin and extends into the gate trenches, and forming a conductive gate electrode on top of the layer of doped type III-nitride semiconductor material.