A method for manufacturing a semiconductor device includes forming an SGT in a semiconductor pillar on a semiconductor substrate and forming a wiring semiconductor layer so as to contact a side surface of an impurity region present in a center portion of the semiconductor pillar or a side surface of a gate conductor layer. A first alloy layer formed in a side surface of the wiring semiconductor layer is directly connected to the impurity region and the gate conductor layer and is connected to an output wiring metal layer through a contact hole formed on an upper surface of a second alloy layer formed in an upper surface and the side surface of the wiring semiconductor layer.

Semiconductor structures and methods of forming the same are provided. A method according to an embodiment includes forming a conductive feature and a first conductive plate over a substrate, conformally depositing a dielectric layer over the conductive feature and the first conductive plate, conformally depositing a conductive layer over the conductive feature and the first conductive plate, and patterning the conductive layer to form a second conductive plate over the first conductive plate and a resistor, the resistor includes a conductive line extending along a sidewall of the conductive feature. By employing the method, a high-resistance resistor may be formed along with a capacitor regardless of the resolution limit of, for example, lithography.

An SRAM includes two Si pillars on a substrate. In the Si pillars, inverter circuits are formed. The inverter circuits include drive N-channel SGTs each including first and second N.sup.+ layers functioning as a source and a drain, and load SGTs each including first and second P.sup.+ layers functioning as a source and a drain. Selection SGTs each including third and fourth N.sup.+ layers functioning as a source and a drain are formed above SiO.sub.2 layers disposed above the inverter circuits. The first N.sup.+ layer is connected to a ground wiring metal layer. The first P.sup.+ layers are connected to a power supply wiring metal layer through a NiSi layer. Gate TiN layers are connected to a word-line wiring metal layer through a NiSi layer. The third N.sup.+ layers are connected to an inverted bit-line wiring metal layer and a bit-line wiring metal layer.

A method is presented for forming a monolithically integrated semiconductor device. The method includes forming a first device including first hydrogenated silicon-based contacts formed on a first portion of a semiconductor material of an insulating substrate and forming a second device including second hydrogenated silicon-based contacts formed on a second portion of the semiconductor material of the insulating substrate. Source and drain contacts of the first device are formed before a gate contact of the first device and a gate contact of the second device is formed before the emitter and collector contacts of the second device. The first device can be a heterojunction field effect transistor (HJFET) and the second device can be a (heterojunction bipolar transistor) HBT. The HJFET and the HBT are integrated in a neuronal circuit and create negative differential resistance by forming a lambda diode.

A method is presented for forming a monolithically integrated semiconductor device. The method includes forming a first device including first hydrogenated silicon-based contacts formed on a first portion of a semiconductor material of an insulating substrate and forming a second device including second hydrogenated silicon-based contacts formed on a second portion of the semiconductor material of the insulating substrate. Source and drain contacts of the first device are formed before a gate contact of the first device and a gate contact of the second device is formed before the emitter and collector contacts of the second device. The first device can be a heterojunction field effect transistor (HJFET) and the second device can be a (heterojunction bipolar transistor) HBT. The HJFET and the HBT are integrated in a neuronal circuit and create negative differential resistance by forming a lambda diode.

A method for producing a semiconductor device includes forming a semiconductor-pillar on a substrate and forming a laminated-structure of at least two composite layers, each including a metal layer and a semiconductor layer in contact with the metal layer, the semiconductor layer containing donor or acceptor atoms, and two interlayer insulating layers sandwiching the composite layers, such that a side surface of at least one of the two interlayer insulating layers is separated from a side surface of the semiconductor pillar. The laminated-structure surrounds the semiconductor pillar. A first heat treatment causes a reaction between the metal layer and the semiconductor layer to form an alloy layer, and brings the alloy layer into contact with the side surface of the semiconductor pillar. A second heat treatment to expands the alloy layer into the semiconductor pillar and diffuses dopant atoms into the semiconductor pillar to form an impurity region therein.

A 3D semiconductor integrated circuit device and a method of manufacturing the same are provided. An active pillar is formed on a semiconductor substrate, and an interlayer insulating layer is formed so that the active pillar is buried in the interlayer insulating layer. The interlayer insulating layer is etched to form a hole so that the active pillar and a peripheral region of the active pillar are exposed. An etching process is performed on the peripheral region of the active pillar exposed through the hole by a certain depth, and a space having the depth is provided between the active pillar and the interlayer insulating layer. A silicon material layer is formed to be buried in the space having the depth, and an ohmic contact layer is formed on the silicon material layer and the active pillar.

An SRAM includes two Si pillars on a substrate. In the Si pillars, inverter circuits are formed. The inverter circuits include drive N-channel SGTs each including first and second N.sup.+ layers functioning as a source and a drain, and load SGTs each including first and second P.sup.+ layers functioning as a source and a drain. Selection SGTs each including third and fourth N.sup.+ layers functioning as a source and a drain are formed above SiO.sub.2 layers disposed above the inverter circuits. The first N.sup.+ layer is connected to a ground wiring metal layer. The first P.sup.+ layers are connected to a power supply wiring metal layer through a NiSi layer. Gate TiN layers are connected to a word-line wiring metal layer through a NiSi layer. The third N.sup.+ layers are connected to an inverted bit-line wiring metal layer and a bit-line wiring metal layer.

A method for producing a semiconductor device includes forming a semiconductor-pillar on a substrate and forming a laminated-structure of at least two composite layers, each including a metal layer and a semiconductor layer in contact with the metal layer, the semiconductor layer containing donor or acceptor atoms, and two interlayer insulating layers sandwiching the composite layers, such that a side surface of at least one of the two interlayer insulating layers is separated from a side surface of the semiconductor pillar. The laminated-structure surrounds the semiconductor pillar. A first heat treatment causes a reaction between the metal layer and the semiconductor layer to form an alloy layer, and brings the alloy layer into contact with the side surface of the semiconductor pillar. A second heat treatment to expands the alloy layer into the semiconductor pillar and diffuses dopant atoms into the semiconductor pillar to form an impurity region therein.

The disclosure relates to a semiconductor device and methods of forming same. A representative structure for a semiconductor device comprises a substrate; a nanowire structure protruding from the substrate having a channel region disposed between a source region and a drain region; a pair of silicide regions extending into opposite sides of the source region, wherein each of the pair of silicide regions comprise a vertical portion adjacent to the source region and a horizontal portion adjacent to the substrate; and a metal gate surrounding a portion the channel region.