Provided are transistors including an electride electrode. The transistor includes a substrate, a source region and a drain region doped with ions of different polarity from the substrate in a surface of the substrate, a source electrode and a drain electrode including an electride material on the source region and the drain region, a gate insulating layer surrounding the source electrode and a drain electrode on the substrate, and a gate electrode between the source electrode and the drain electrode on the substrate. The source electrode and the drain electrode have an ohmic contact with the substrate.

An electrical contact structure (an MIS contact) includes one or more conductors (M-Layer), a semiconductor (S-Layer), and an interfacial dielectric layer (I-Layer) of less than 4 nm thickness disposed between and in contact with both the M-Layer and the S-Layer. The I-Layer is an oxide of a metal or a semiconductor. The conductor of the M-Layer that is adjacent to and in direct contact with the I-Layer is a metal oxide that is electrically conductive, chemically stable and unreactive at its interface with the I-Layer at temperatures up to 450 C. The electrical contact structure has a specific contact resistivity of less than or equal to approximately 10.sup.5-10.sup.7 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 210.sup.19 cm.sup.3 and less than approximately 10.sup.8 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 10.sup.20 cm.sup.3.

A semiconductor component is disclosed. The semiconductor component can include: a semiconductor layer injected with a same type of dopant; a gate electrode formed above the semiconductor layer with a gate insulation film positioned in-between; a dielectric layer formed on the semiconductor layer at both sides of the gate electrode; and source/drain electrodes each formed on the dielectric layer.

Energy-filtered cold electron devices use electron energy filtering through discrete energy levels of quantum wells or quantum dots that are formed through band bending of tunneling barrier conduction band. These devices can obtain low effective electron temperatures of less than or equal to 45K at room temperature, steep electrical current turn-on/turn-off capabilities with a steepness of less than or equal to 10 mV/decade at room temperature, subthreshold swings of less than or equal to 10 mV/decade at room temperature, and/or supply voltages of less than or equal to 0.1 V.

In accordance with an embodiment, a method includes switching on a transistor device by generating a first conducting channel by driving a first gate electrode and, before generating the first conducting channel, generating a second conducting channel by driving a second gate electrode, wherein the second gate electrode is adjacent the first gate electrode in a current flow direction of the transistor device.

A method of making a quantum device with a quantum island structure is provided. The method includes the formation of a stack including a first semiconducting layer based on an undoped semiconducting material on which at least one second doped semiconducting layer is grown by epitaxy, the doping being made during epitaxial growth, a first region belonging to the first semiconducting layer and a second region belonging to the second semiconducting layer being suitable for forming a quantum island.

A method of constructing an electrical contact including a contact element positioned between a first contact member and a second contact member. The method includes defining a transmission line model to represent operation of the electrical contact. The transmission line model indicates a contact resistance and a specific contact resistivity along a length of the contact element. The method includes determining a current flow profile of the contact element. The current flow profile is determined based on a current distribution using the transmission line model. The method includes determining one of: (i) a material, (ii) a thickness, and (iii) a geometry of the contact element based on the contact resistance and the current flow profile of the transmission line model. The method includes constructing the contact element positioned between the first contact member and the second contact member with the at least one of (i) the material, (ii) the thickness, and (iii) the geometry.

An electrical contact structure (an MIS contact) includes one or more conductors (M-Layer), a semiconductor (S-Layer), and an interfacial dielectric layer (I-Layer) of less than 4 nm thickness disposed between and in contact with both the M-Layer and the S-Layer. The I-Layer is an oxide of a metal or a semiconductor. The conductor of the M-Layer that is adjacent to and in direct contact with the I-Layer is a metal oxide that is electrically conductive, chemically stable and unreactive at its interface with the I-Layer at temperatures up to 450 C. The electrical contact structure has a specific contact resistivity of less than or equal to approximately 10.sup.5-10.sup.7 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 210.sup.19 cm.sup.3 and less than approximately 10.sup.8 -cm.sup.2 when the doping in the semiconductor adjacent the MIS contact is greater than approximately 10.sup.20 cm.sup.3.

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

A semiconductor device includes at least one active pattern on a substrate, at least one gate electrode intersecting the at least one active pattern, source/drain regions on the at least one active pattern, the source/drain regions being on opposite sides of the at least one gate electrode, and a barrier layer between at least one of the source/drain regions and the at least one active pattern, the barrier layer being at least on bottoms of the source/drain regions and including oxygen.