The present invention relates generally to integrated circuits and more particularly, to a structure and method of forming a hybrid circuit including a tunnel field-effect transistor (TFET) and a conventional field effect transistor (FET). Embodiments of the present invention include a hybrid amplifier which features a TFET common-source feeding a common-gate conventional FET (e.g. a MOSFET). A TFET gate may be electrically isolated from an output from a conventional FET. Thus, a high impedance input may be received by a TFET with a high-isolation output (i.e. low capacitance) at a conventional FET. A hybrid circuit amplifier including a TFET and a conventional FET may have a very high input impedance and a low miller capacitance.

A Tunnel Field-Effect Transistor (TFET) device is provided comprising at least one heterosection between the source region and the channel region. The at least one heterosection has a low dielectric constant and thickness below 10 nm. Additionally a pocket region and another heterosection may be added in between the at least one heterosection and the channel region.

There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

A MOSFET device or a rectifier device with improved RDSON and BV performance has a repetitive pattern of field plate trenches disposed in a semiconductor chip. The semiconductor chip comprises a doped epi-layer, in which the dopant concentration progressively decreases from the top of the chip surface towards the bottom of the chip. The doped epi-layer may comprises strata of epi-layers of different dopant concentrations and the field plate trenches each terminate at a predetermined point in the strata.

A semiconductor arrangement and methods of formation are provided. A semiconductor arrangement includes a semiconductor column on a buffer layer over a substrate. The buffer layer comprises a conductive material. Both a first end of the semiconductor column and a bottom contact are connected to a buffer layer such that the first end of the semiconductor column and the bottom contact are connected to one another through the buffer layer, which reduces a contact resistance between the semiconductor column and the bottom contact. A second end of the semiconductor column is connected to a top contact. In some embodiments, the first end of the semiconductor column corresponds to a source or drain of a transistor and the second end corresponds to the drain or source of the transistor.

Described is a memory bit-cell comprising: a storage node; an access transistor coupled to the storage node; a capacitor having a first terminal coupled to the storage node; and one or more negative differential resistance devices coupled to the storage node such that the memory bit-cell is without one of a ground line or a supply line or both.

In a particular embodiment, an apparatus includes an electron tunnel structure. The electron tunnel structure includes a tunneling layer, a channel layer, a source layer, and a drain layer. The tunneling layer and the channel layer are positioned between the source layer and the drain layer. The transistor device further includes a high-k dielectric layer adjacent to the electron tunnel structure.

An embodiment integrated circuit (e.g., diode) and method of making the same. The embodiment integrated circuit includes a well having a first doping type formed over a substrate having the first doping type, the well including a fin, a source formed over the well on a first side of the fin, the source having a second doping type, a drain formed over the well on a second side of the fin, the drain having the first doping type, and a gate oxide formed over the fin, the gate oxide laterally spaced apart from the source by a back off region of the fin. The integrated circuit is compatible with a FinFET fabrication process.

Embodiments of the present disclosure describe multi-layer graphene assemblies including a layer of fluorinated graphene, dies and systems containing such structures, as well as methods of fabrication. The fluorinated graphene provides an insulating interface to other graphene layers while maintaining the desirable characteristics of the nonfluorinated graphene layers. The assemblies provide new options for utilizing graphene in integrated circuit devices and interfacing graphene with other materials. Other embodiments may be described and/or claimed.

Neural signal amplifiers include an operational amplifier and a feedback network coupled between an output and an input thereof. The feedback network includes a tunnel field effect transistor (TFET) pseudo resistor that exhibits bi-directional conductivity. A drain region of the TFET may be electrically connected to the gate electrode thereof to provide a bi-directional resistor having good symmetry in terms of resistance as a function of voltage polarity.