An IC structure includes first and second semiconductor fins extending along a first direction; first and second gate electrodes respectively extending across channel regions of the first and second semiconductor fins along a second direction perpendicular to the first direction; first and second source/drain contacts extending across source/drain regions of the first and second semiconductor fins, respectively; and first source/drain via over the first source/drain contact, wherein a width of the second source/drain contact measured along the first direction is greater than a diameter of the first source/drain via.

A device includes: a gate line on an active region of a substrate, a pair of source/drain regions in the active region on both sides of the gate line, a contact plug on at least one source/drain region out of the pair of source/drain regions; and a multilayer-structured insulating spacer between the gate line and the contact plug. The multilayer-structured insulating spacer may include an oxide layer, a first carbon-containing insulating layer covering a first surface of the oxide layer adjacent to the gate line, and a second carbon-containing insulating layer covering a second surface of the oxide layer, opposite to the first surface of the oxide layer, adjacent to the contact plug.

Semiconductor devices and methods of fabricating semiconductor devices are provided. The present disclosure provides a semiconductor device that includes a first fin structure and a second fin structure each extending from a substrate; a first gate segment over the first fin structure and a second gate segment over the second fin structure; a first isolation feature separating the first and second gate segments; a first source/drain (S/D) feature over the first fin structure and adjacent to the first gate segment; a second S/D feature over the second fin structure and adjacent to the second gate segment; and a second isolation feature also disposed in the trench. The first and second S/D features are separated by the second isolation feature, and a composition of the second isolation feature is different from a composition of the first isolation feature.

A method for producing an FET transistor includes producing a transistor channel, comprising at least one semiconductor nanowire arranged on a substrate and comprising first and second opposite side faces; producing at least two dummy gates, each arranged against one of the first and second side faces of the channel; etching a first of the two dummy gates, forming a first gate location against the first side face of the channel; producing a first gate in the first gate location and against the first side face of the channel; etching a second of the two dummy gates, forming a second gate location against the second side face of the channel; and producing a second gate in the second gate location and against the second side face of the channel.

A semiconductor arrangement includes: a substrate; fins formed on the substrate and extending in a first direction; gate stacks formed on the substrate and each extending in a second direction crossing the first direction to intersect at least one of the fins, and dummy gates composed of a dielectric and extending in the second direction; spacers formed on sidewalls of the gate stacks and the dummy gates; and dielectric disposed between first and second ones of the gate stacks in the second direction to electrically isolate the first and second gate stacks. The dielectric is disposed in a space surrounded by respective spacers of the first and second gate stacks which extend integrally. At least a portion of an interval between the first and second gate stacks in the second direction is less than a line interval achievable by lithography in a process of manufacturing the semiconductor arrangement.

Techniques are disclosed for customization of nanowire transistor devices to provide a diverse range of channel configurations and/or material systems within the same integrated circuit die. In accordance with one example embodiment, sacrificial fins are removed and replaced with custom material stacks of arbitrary composition and strain suitable for a given application. In one such case, each of a first set of the sacrificial fins is recessed or otherwise removed and replaced with a p-type layer stack, and each of a second set of the sacrificial fins is recessed or otherwise removed and replaced with an n-type layer stack. The p-type layer stack can be completely independent of the process for the n-type layer stack, and vice-versa. Numerous other circuit configurations and device variations are enabled using the techniques provided herein.

Embodiments of mechanisms for forming dislocations in source and drain regions of finFET devices are provided. The mechanisms involve recessing fins and removing the dielectric material in the isolation structures neighboring fins to increase epitaxial regions for dislocation formation. The mechanisms also involve performing a pre-amorphous implantation (PAI) process either before or after the epitaxial growth in the recessed source and drain regions. An anneal process after the PAI process enables consistent growth of the dislocations in the source and drain regions. The dislocations in the source and drain regions (or stressor regions) can form consistently to produce targeted strain in the source and drain regions to improve carrier mobility and device performance for NMOS devices.

A semiconductor device includes an insulator on a substrate and having opposite first and second sides that each extend along a first direction, a first fin pattern extending from a third side of the insulator along the first direction, a second fin pattern extending from a fourth side of the insulator along the first direction, and a first gate structure extending from the first side of the insulator along a second direction transverse to the first direction. The device further includes a second gate structure extending from the second side of the insulator along the second direction, a third fin pattern overlapped by the first gate structure, spaced apart from the first side of the insulator, and extending along the first direction, and a fourth fin pattern which overlaps the second gate structure, is spaced apart from the second side, and extends in the direction in which the second side extends. An upper surface of the insulator is higher than an upper surface of the first fin pattern and an upper surface of the second fin pattern.

A method of forming a device on a substrate with recessed first/third areas relative to a second area by forming a fin in the second area, forming first source/drain regions (with first channel region therebetween) by first/second implantations, forming second source/drain regions in the third area (defining second channel region therebetween) by the second implantation, forming third source/drain regions in the fin (defining third channel region therebetween) by third implantation, forming a floating gate over a first portion of the first channel region by first polysilicon deposition, forming a control gate over the floating gate by second polysilicon deposition, forming an erase gate over the first source region and a device gate over the second channel region by third polysilicon deposition, and forming a word line gate over a second portion of the first channel region and a logic gate over the third channel region by metal deposition.

A semiconductor device is provided, which includes a substrate, an active region, source and drain regions, first and second gate structures, and a contact structure. The active region is arranged over the substrate and the source and drain regions are arranged in the active region. The first and second gate structures abut upon the active region. The first gate structure is arranged between the source and drain regions and the second gate structure is arranged between the first gate structure and the drain region. The contact structure is arranged over the active region electrically coupling the first gate structure.