A method of making a semiconductor device includes forming a source/drain region on a substrate; disposing a gate stack on the substrate and adjacent to the source/drain region, the gate stack including a gate spacer along a sidewall of the gate stack; disposing an inter-level dielectric (ILD) layer on the source/drain region and the gate stack; removing a portion of the ILD layer on the source/drain region to form a source/drain contact pattern; filling the source/drain contact pattern with a layer of silicon material, the layer of silicon material being in contact with the source/drain region and in contact with the gate spacer; depositing a metallic layer over the first layer of silicon material; and performing a silicidation process to form a source/drain contact including a silicide.

A structure includes a substrate and a tunnel field effect transistor (TFET). The TFET includes a source region disposed in the substrate having an overlying source contact, the source region containing first semiconductor material having a first doping type; a drain region disposed in the substrate having an overlying drain contact, the drain region containing second semiconductor material having a second, opposite doping type; and a gate structure that overlies a channel region between the source and the drain. The source region and the drain region are asymmetric with respect to one another such that one contains a larger volume of semiconductor material than the other one. A method is disclosed to fabricate a plurality of the TFETs using a plurality of spaced apart mandrels having spacers. A pair of the mandrels and the associated spacers is processed to form four adjacent TFETs without requiring intervening lithographic processes.

A structure includes a substrate and a tunnel field effect transistor (TFET). The TFET includes a source region disposed in the substrate having an overlying source contact, the source region containing first semiconductor material having a first doping type; a drain region disposed in the substrate having an overlying drain contact, the drain region containing second semiconductor material having a second, opposite doping type; and a gate structure that overlies a channel region between the source and the drain. The source region and the drain region are asymmetric with respect to one another such that one contains a larger volume of semiconductor material than the other one. A method is disclosed to fabricate a plurality of the TFETs using a plurality of spaced apart mandrels having spacers. A pair of the mandrels and the associated spacers is processed to form four adjacent TFETs without requiring intervening lithographic processes.

A semiconductor device including a channel region formed in a semiconductor substrate; a source region formed on one side of the channel region; a drain region formed on the other side of the channel region; a gate electrode formed on the channel region with a gate insulating film therebetween; and a stress-introducing layer that applies stress to the channel region, the semiconductor device having a stress distribution in which source region-side and drain region-side peaks are positioned between a pn junction boundary of the channel region and the source region and a pn junction boundary of the channel region and the drain region.

Metal quantum dots are incorporated into doped source and drain regions of a MOSFET array to assist in controlling transistor performance by altering the energy gap of the semiconductor crystal. In a first example, the quantum dots are incorporated into ion-doped source and drain regions. In a second example, the quantum dots are incorporated into epitaxially doped source and drain regions.

A semiconductor device including a memory cell featuring a first gate insulating film over a semiconductor substrate, a control gate electrode over the first gate insulating film, a second gate insulating film over the substrate and a side wall of the control gate electrode, a memory gate electrode over the second gate insulating film arranged adjacent with the control gate electrode through the second gate insulating film, first and second semiconductor regions in the substrate positioned on a control gate electrode side and a memory gate side, respectively, the second gate insulating film featuring a first film over the substrate, a charge storage film over the first film and a third film over the second film, the first film having a first portion between the substrate and memory gate electrode and a thickness greater than that of a second portion between the control gate electrode and the memory gate electrode.

Process of using a dummy gate as an interconnection and a method of manufacturing the same are disclosed. Embodiments include forming on a semiconductor substrate dummy gate structures at cell boundaries, each dummy gate structure including a set of sidewall spacers and a cap disposed between the sidewall spacers; removing a first sidewall spacer or at least a portion of a first cap on a first side of a first dummy gate structure and forming a first gate contact trench over the first dummy gate structure; and filling the first gate contact trench with a metal to form a first gate contact.

An integrated circuit includes a silicon on insulator substrate having a semiconductor film located above a buried insulating layer. At least one memory cell of the one-time-programmable type includes an MOS capacitor having a first electrode region including a gate region at least partially silicided and flanked by an insulating lateral region, a dielectric layer located between the gate region and the semiconductor film, and a second electrode region including a silicided zone of the semiconductor film, located alongside the insulating lateral region and extending at least partially under the dielectric layer.

A nanocrystalline diamond layer for use in forming a semiconductor device and methods for using the same are disclosed herein. The device can include a substrate with a processing surface and a supporting surface, a device layer formed on the processing surface and a nanocrystalline diamond layer formed on the processing layer, the nanocrystalline diamond layer having an average grain size of between 2 nm and 5 nm. The method can include positioning a substrate in a process chamber, depositing a device layer on a processing surface, depositing a nanocrystalline diamond layer on the device layer, the nanocrystalline diamond layer having an average grain size of between 2 nm and 5 nm, patterning and etching the nanocrystalline diamond layer, etching the device layer to form a feature and ashing the nanocrystalline diamond layer from the surface of the device layer.

A semiconductor device includes a semiconductor substrate, an insulating film located on the semiconductor substrate, a silicon film located on the insulating film, a silicide layer located on the silicon film, and a first contact and a second contact connected to portions of the silicide layer. A first recess is formed in an upper surface of the insulating film. The silicon film includes an impurity. A second recess is formed in an upper surface of the silicon film in a region directly above the first recess. The silicide layer contacts the silicon film. A region directly above the second recess is interposed between the portions.