Among other things, one or more techniques for forming a vertical tunnel field effect transistor (FET), and a resulting vertical tunnel FET are provided herein. In an embodiment, the vertical tunnel FET is formed by forming a core over a first type substrate region, forming a second type channel shell around a circumference greater than a core circumference, forming a gate dielectric around a circumference greater than the core circumference, forming a gate electrode around a circumference greater than the core circumference, and forming a second type region over a portion of the second type channel shell, where the second type has a doping opposite a doping of the first type. In this manner, line tunneling is enabled, thus providing enhanced tunneling efficiency for a vertical tunnel FET.

Tunneling field effect transistors (TFETs) including a variable bandgap channel are described. In some embodiments, one or more bandgap characteristics of the variable bandgap channel may be dynamically altered by at least one of the application or withdrawal of a force, such as a voltage or electric field. In some embodiments the variable bandgap channel may be configured to modulate from an ON to an OFF state and vice versa in response to the application and/or withdrawal of a force. The variable bandgap channel may exhibit a bandgap that is smaller in the ON state than in the OFF state. As a result, the TFETs may exhibit one or more of relatively high on current, relatively low off current, and sub-threshold swing below 60 mV/decade.

Tunneling field effect transistors and fabrication methods thereof are provided, which include: an integrated circuit device which includes a circuit input configured to receive an input voltage and a circuit output configured to deliver an output current. The integrated circuit also includes a circuit element having at least one tunneling field effect transistor (TFET). The circuit element connects the circuit input to the circuit output and is characterized by a V-shaped current-voltage diagram. The V-shaped current-voltage diagram describes the relationship between the input voltage of the circuit input and the output current of the circuit output.

A fin tunnel field effect transistor includes a seed region and a first type region disposed above the seed region. The first type region includes a first doping. The fin tunnel field effect transistor includes a second type region disposed above the first type region. The second type region includes a second doping that is opposite the first doping. The fin tunnel field effect transistor includes a gate insulator disposed above the second type region and a gate electrode disposed above the gate insulator. A method for forming an example fin tunnel field effect transistor is provided.

The present disclosure relates to an intra-band tunnel FET, which has a symmetric FET that is able to provide for a high drive current. In some embodiments, the disclosed intra-band tunnel FET has a source region having a first doping type and a drain region having the first doping type. The source region and the drain region are separated by a channel region. A gate region may generate an electric field that varies the position of a valence band and/or a conduction band in the channel region. By controlling the position of the valence band and/or the conduction band of the channel region, quantum mechanical tunneling of charge carries between the conduction band in the source region and in the drain region or between the valence band in the source region and in the drain region can be controlled.

The present invention provides a semiconductor element that can be manufactured easily at a low cost, can obtain a high tunneling current, and has an excellent operating characteristic, a method for manufacturing the same, and a semiconductor integrated circuit including the semiconductor element. The semiconductor element of the present invention is characterized in that the whole or a part of a tunnel junction is constituted by a semiconductor region made of an indirect-transition semiconductor containing isoelectronic-trap-forming impurities.

A tunneling field-effect transistor may be provided that includes: a substrate; a source which is formed on the substrate and into which p+ type impurity ion is injected; a drain which is formed on the substrate and into which n+ type impurity ion is injected; a plurality of vertically stacked nanowire channels which are formed on the substrate; a gate insulation layer which is formed on the plurality of nanowire channels; and a gate which is formed on the gate insulation layer. As a result, it is possible to generate a higher driving current without changing the length of the gate and the area of the channel (degree of integration).

A method of manufacturing a semiconductor device includes preparing a light ion source, a first mask and a second mask. A side of a first region on a top surface of a semiconductor substrate is shielded by using the first mask. The top surface, with the side of the first region thereon being shielded with the first mask, is irradiated with light ions by operating the light ion source to introduce lattice defects at a specified depth on a side of a second region on the top surface. A side of the second region on a bottom surface of the semiconductor substrate is shielded by using the second mask. The bottom surface, with the side of the second region thereon being shielded with the second mask, is irradiated with light ions by operating the light ion source to introduce lattice defects at a specified depth on the side of the first region on the bottom surface.

A semiconductor device and method of manufacturing a semiconductor device using a semiconductor fin is provided. In an embodiment the fin is formed from a substrate, a middle section of the fin is covered, and then portions of the fin on either side of the middle section are removed. A series of implants is then performed and a gate dielectric and a gate electrode are formed to form a tunneling field effect transistor from the fin.

A semiconductor memory device may include a pillar, a gate and at least one ferroelectric layer. The pillar may include a source, a drain and a channel region. The drain may be arranged over the source. The channel region may be arranged between the source and the drain. The gate may be formed on an outer surface of the pillar. The ferroelectric layer may be interposed between the pillar and the gate.