A device and structure for providing electrostatic discharge (ESD) protection. Schottky barrier diode (SBD) structure comprising a substrate of a first dopant polarity, a well region of a second dopant polarity formed on or within said substrate, an anode region of a first dopant polarity, a cathode of a second polarity, and a rectifying contact on said anode and/or said cathode, wherein said rectifying contact is formed substantially near the surface of said substrate to provide a rectifying barrier junction between the conducting layer and the semiconductor substrate, providing electrical coupling in said Schottky Barrier diode structure. The disclosure further includes SOI Schottky Barrier polysilicon-bound diodes (also known as Lubistor structures). Additionally, a diode configured SOI dynamic threshold MOSFET with rectifying barrier junctions on the drain or source region.

Disclosed is a technique capable of reducing loss at the time of switching in a diode. A diode disclosed in the present specification includes a cathode electrode, a cathode region made of a first conductivity type semiconductor, a drift region made of a low concentration first conductivity type semiconductor, an anode region made of a second conductivity type semiconductor, an anode electrode made of metal, a barrier region formed between the drift region and the anode region and made of a first conductivity type semiconductor having a concentration higher than that of the drift region, and a pillar region formed so as to connect the barrier region to the anode electrode and made of a first conductivity type semiconductor having a concentration higher than that of the barrier region. The pillar region and the anode are connected through a Schottky junction.

The field effect transistor (FET) of the present subject matter comprises a bottom gate electrode, a bottom gate dielectric provided on the bottom gate electrode, a channel layer provided on the bottom gate dielectric. A top portion comprising a source electrode, a drain electrode, a top gate electrode provided, and a top dielectric layer is provided on the channel layer. The channel layer forms Schottky barriers at points of contact with the source and the drain electrode. A back-gate voltage varies a height and a top-gate voltage varies a width of the Schottky barrier. The FET can be programmed to work in two operating modes-tunnelling (providing low power consumption) and thermionic mode (providing high performance). The FET can also be programmed to combine the tunnelling and thermionic mode in a single operating cycle, yielding high performance with low power consumption.

Semiconductor devices and method of forming the same include forming a sacrificial layer on source/drain regions of a semiconductor layer. A reactant layer is formed on the sacrificial layer. The reactant layer and sacrificial layer are annealed to convert the reactant layer to a dielectric layer. Source and drain regions are formed on the dielectric layer.

A method of forming a semiconductor device can be provided by forming an opening that exposes a surface of an elevated source/drain region. The size of the opening can be reduced and a pre-amorphization implant (PAI) can be performed into the elevated source/drain region, through the opening, to form an amorphized portion of the elevated source/drain region. A metal-silicide can be formed from a metal and the amorphized portion.

In one general aspect, a device can include a first trench disposed in a semiconductor region, a second trench disposed in the semiconductor region, and a recess disposed in the semiconductor region between the first trench and the second trench. The recess has a sidewall and a bottom surface. The device also includes a Schottky interface along a sidewall of the recess and the bottom surface of the recess excludes a Schottky interface.

A Schottky contact structure for a semiconductor device having a Schottky contact and an electrode for the contact structure disposed on the contact. The Schottky contact comprises: a first layer of a first metal in Schottky contact with a semiconductor; a second layer of a second metal on the first layer; a third layer of the first metal on the second layer; and a fourth layer of the second metal on the third layer. The electrode for the Schottky contact structure disposed on the Schottky contact comprises a third metal, the second metal providing a barrier against migration between the third metal and the first metal.

Ferroelectric-modulated Schottky non-volatile memory is disclosed. A resistive memory element is provided that is based on a semiconductive material. Metal elements are formed on a semiconductive material at two places such that two semiconductor-metal junctions are formed. The semiconductive material with the two semiconductor-metal junctions establishes a composite resistive element having a resistance and functions as a relatively fast switch with a relatively low forward voltage drop. Each metal element may couple a terminal to the resistive element. To provide a resistive element capable of being a resistive memory element to store distinctive memory states, a ferroelectric material is provided and disposed adjacent to the semiconductive material to create an electric field from a ferroelectric dipole. The orientation of the ferroelectric dipole changes the resistance of the resistive element to allow it to function as a resistive memory element.

An electrical device in which an interface layer is disposed in between and in contact with a conductor and a semiconductor.

Provided are a graphene-metal bonding structure, a method of manufacturing the graphene-metal bonding structure, and a semiconductor device including the graphene-metal bonding structure. According to example embodiments, a graphene-metal bonding structure includes: a graphene layer; a metal layer on the graphene layer; and an intermediate material layer between the graphene layer and the metal layer. The intermediate material layer forms an edge-contact with the metal layer from boundary portions of a material contained in the intermediate material layer that contact the metal layer.