Abstract: A fin field effect transistor (FinFET) ESD device is disclosed. The device may include: a substrate; a silicon-controlled rectifier (SCR) over the substrate, the SCR including: a p-well region over the substrate; an n-well region laterally abutting the p-well region over the substrate; a first P+ doped region over the p-well region; a first N+ doped region over the p-well region; and a second N+ doped region over the p-well region; and a Schottky diode electrically coupled to the n-well region, wherein the Schottky diode spans the n-well region and the p-well region, and wherein the Schottky diode controls electrostatic discharge (ESD) between the second N+ doped region and the n-well region.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to transistor structures and methods of manufacture. The structure includes active metal lines separated by electrically floating metal layers which have a width less than a width of the active metal lines.

Abstract: Methods, apparatus, and systems relating to a MOSFET with ESD resistance, specifically, to a semiconductor device comprising a field-effect transistor (FET) comprising a gate, a source, and a drain, all extending parallel to each other in a first direction; at least one source electrostatic discharge (ESD) protection circuit; a source terminal disposed above and in electrical contact with the at least one source ESD protection circuit, wherein the source terminal extends in the first direction; at least one drain ESD protection circuit; and a drain terminal disposed above and in electrical contact with the at least one drain ESD protection circuit, wherein the drain terminal extends in the first direction.

Abstract: High-voltage semiconductor devices with electrostatic discharge (ESD) protection and methods of fabrication are provided. The semiconductor devices include a plurality of transistors on a substrate patterned with one or more common gates extending across a portion of the substrate, and a plurality of first S/D contacts and a plurality of second S/D contacts associated with the common gate(s). The second S/D contacts are disposed over a plurality of carrier-doped regions within the substrate. One or more floating nodes are disposed above the substrate and, at least in part, between second S/D contacts to facilitate defining the plurality of carrier-doped regions within the substrate. For instance, the carrier-doped regions may be defined from a mask with a common carrier-region opening, with the floating node(s) intersecting the common carrier-region opening and facilitating defining, along with the common opening, the plurality of separate carrier-doped regions.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to transistor structures and methods of manufacture. The structure includes active metal lines separated by electrically floating metal layers which have a width less than a width of the active metal lines.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to transistor structures and methods of manufacture. The structure includes active metal lines separated by electrically floating metal layers which have a width less than a width of the active metal lines.

Abstract: Structures for a frequency divider, methods of fabricating a frequency divider, and method of using a frequency divider. A first interconnect line is configured to selectively conduct a first signal of a first frequency. A second interconnect line is coupled with the first interconnect line. The second interconnect line is configured to selectively conduct a second signal of a second frequency. The first frequency is less the second frequency.

Abstract: Structures for a frequency divider, methods of fabricating a frequency divider, and method of using a frequency divider. A first interconnect line is configured to selectively conduct a first signal of a first frequency. A second interconnect line is coupled with the first interconnect line. The second interconnect line is configured to selectively conduct a second signal of a second frequency. The first frequency is less the second frequency.

Abstract: Various embodiments include fin-type field effect transistor (FinFET) structures. In some cases, a FinFET structure includes: a p-type substrate; a silicon-controlled rectifier (SCR) over the p-type substrate, the SCR including: a p-well region and an adjacent n-well region over the substrate; and a negatively charged fin over the p-well region; and a Schottky diode electrically coupled with the SCR, the Schottky diode including a gate in the n-well region, the Schottky diode positioned to mitigate electrostatic discharge (ESD) across the negatively charged fin and the n-well region in response to application of a forward voltage across the gate.

Abstract: Methods form integrated circuit structures that include a device layer having electronic devices on a substrate, and a multi-layer interconnect structure connected to the device layer. The multi-layer interconnect structure includes alternating insulator layers and wiring layers, power and ground wiring in the wiring layers, non-functional wiring in the wiring layers called dummy fill, and conductive vias extending through the insulator layers. The conductive vias connect the power and ground wiring in the wiring layers to the electronic devices in the device layer. The non-functional wiring is insulated from the power wiring in the wiring layer, and from the electronic devices in the device layer. The conductive vias connect the non-functional wiring (the dummy fill) in the wiring layers through the substrate, or a ground bus, thereby continuously removing static charge that would otherwise accumulate during manufacturing processes.

Abstract: Methods, apparatus, and systems relating to a MOSFET with ESD resistance, specifically, to a semiconductor device comprising a field-effect transistor (FET) comprising a gate, a source, and a drain, all extending parallel to each other in a first direction; at least one source electrostatic discharge (ESD) protection circuit; a source terminal disposed above and in electrical contact with the at least one source ESD protection circuit, wherein the source terminal extends in the first direction; at least one drain ESD protection circuit; and a drain terminal disposed above and in electrical contact with the at least one drain ESD protection circuit, wherein the drain terminal extends in the first direction.

Abstract: Methods to forming trigger-voltage tunable cascode transistors for an ESD protection circuit in FinFET IC devices and resulting devices. Embodiments include providing a substrate including adjacent first-type well areas, over the substrate, each pair of first-type well areas separated by a second-type well area; providing one or more junction areas in each first and second type well area, each junction area being a first type or a second type; forming fins, spaced from each other, perpendicular to and over the first and second type junction areas; and forming junction-type devices by forming electrical connections between the first and second type junction areas in the first-type well areas and the substrate, wherein a first-stage junction-type device in a first-type well area includes stacked first and second type junction areas, and wherein the first-stage junction-type device is adjacent a second-type well area including first and second type junction areas.

Abstract: High-voltage semiconductor devices with electrostatic discharge (ESD) protection and methods of fabrication are provided. The semiconductor devices include a plurality of transistors on a substrate patterned with one or more common gates extending across a portion of the substrate, and a plurality of first S/D contacts and a plurality of second S/D contacts associated with the common gate(s). The second S/D contacts are disposed over a plurality of carrier-doped regions within the substrate. One or more floating nodes are disposed above the substrate and, at least in part, between second S/D contacts to facilitate defining the plurality of carrier-doped regions within the substrate. For instance, the carrier-doped regions may be defined from a mask with a common carrier-region opening, with the floating node(s) intersecting the common carrier-region opening and facilitating defining, along with the common opening, the plurality of separate carrier-doped regions.

Abstract: Various embodiments include fin-type field effect transistor (FinFET) structures. In some cases, a FinFET structure includes: a p-type substrate; a silicon-controlled rectifier (SCR) over the p-type substrate, the SCR including: a p-well region and an adjacent n-well region over the substrate; and a negatively charged fin over the p-well region; and a Schottky diode electrically coupled with the SCR, the Schottky diode including a gate in the n-well region, the Schottky diode positioned to mitigate electrostatic discharge (ESD) across the negatively charged fin and the n-well region in response to application of a forward voltage across the gate.

Abstract: Methods, apparatus, and systems relating to a MOSFET with ESD resistance, specifically, to a semiconductor device comprising a field-effect transistor (FET) comprising a gate, a source, and a drain, all extending parallel to each other in a first direction; at least one source electrostatic discharge (ESD) protection circuit; a source terminal disposed above and in electrical contact with the at least one source ESD protection circuit, wherein the source terminal extends in the first direction; at least one drain ESD protection circuit; and a drain terminal disposed above and in electrical contact with the at least one drain ESD protection circuit, wherein the drain terminal extends in the first direction.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to transistor structures and methods of manufacture. The structure includes active metal lines separated by electrically floating metal layers which have a width less than a width of the active metal lines.

Abstract: Various embodiments include fin-type field effect transistor (FinFET) structures. In some cases, a FinFET structure includes: a substrate; a silicon-controlled rectifier (SCR) over the substrate, the SCR including: a p-well region and an adjacent n-well region over the substrate; and a negatively charged fin over the p-well region; and a Schottky diode electrically coupled with the SCR, the Schottky diode spanning between the p-well region and the n-well region, the Schottky diode for controlling electrostatic discharge (ESD) across the negatively charged fin and the n-well region.

Abstract: High-voltage semiconductor devices with electrostatic discharge (ESD) protection and methods of fabrication are provided. The semiconductor devices include a plurality of transistors on a substrate patterned with one or more common gates extending across a portion of the substrate, and a plurality of first S/D contacts and a plurality of second S/D contacts associated with the common gate(s). The second S/D contacts are disposed over a plurality of carrier-doped regions within the substrate. One or more floating nodes are disposed above the substrate and, at least in part, between second S/D contacts to facilitate defining the plurality of carrier-doped regions within the substrate. For instance, the carrier-doped regions may be defined from a mask with a common carrier-region opening, with the floating node(s) intersecting the common carrier-region opening and facilitating defining, along with the common opening, the plurality of separate carrier-doped regions.

Abstract: A fin field effect transistor (FinFET) ESD device is disclosed. The device may include: a substrate; a silicon-controlled rectifier (SCR) over the substrate, the SCR including: a p-well region over the substrate; an n-well region laterally abutting the p-well region over the substrate; a first P+ doped region over the p-well region; a first N+ doped region over the p-well region; and a second N+ doped region over the p-well region; and a Schottky diode electrically coupled to the n-well region, wherein the Schottky diode spans the n-well region and the p-well region, and wherein the Schottky diode controls electrostatic discharge (ESD) between the second N+ doped region and the n-well region.

Abstract: Various embodiments include fin-type field effect transistor (FinFET) structures. In some cases, a FinFET structure includes: a substrate; a silicon-controlled rectifier (SCR) over the substrate, the SCR including: a p-well region and an adjacent n-well region over the substrate; and a negatively charged fin over the p-well region; and a Schottky diode electrically coupled with the SCR, the Schottky diode spanning between the p-well region and the n-well region, the Schottky diode for controlling electrostatic discharge (ESD) across the negatively charged fin and the n-well region.