Abstract: Structures including a waveguide arrangement and methods of fabricating a structure that includes a waveguide arrangement. A second waveguide spaced in a lateral direction from a first waveguide, a third waveguide spaced in a vertical direction from the first waveguide, and a fourth waveguide spaced in the vertical direction from the second waveguide. The third waveguide is arranged in the lateral direction to provide a first overlapping relationship with the first waveguide. The fourth waveguide is arranged in the lateral direction to provide a second overlapping relationship with the second waveguide.

Abstract: A large area electrical contact for use in integrated circuits features a non-planar, sloped bottom profile. The sloped bottom profile provides a larger electrical contact area, thus reducing the contact resistance, while maintaining a small contact footprint. The sloped bottom profile can be formed by recessing an underlying layer, wherein the bottom profile can be crafted to have a V-shape, U-shape, crescent shape, or other profile shape that includes at least a substantially sloped portion in the vertical direction. In one embodiment, the underlying layer is an epitaxial fin of a FinFET. A method of fabricating the low-resistance electrical contact employs a thin etch stop liner for use as a hard mask. The etch stop liner, e.g., HfO2, prevents erosion of an adjacent gate structure during the formation of the contact.

Abstract: A vertical fin field effect transistor includes a semiconductor fin disposed over a well region and a gate conductor layer disposed over a sidewall of the fin, and extending laterally over a top surface of the well region adjacent to the fin. The extension of the gate conductor over the bottom source/drain effectively increases the channel length of the vertical FinFET device independent of the fin height. A bottom source/drain region is laterally adjacent to the well region such that the portion of the well region covered by the laterally extended gate stack is between the bottom source/drain region and the portion of the well region immediately under the fin. A top source/drain region is located above the fin. The device is operated in circuits by use of electrical contacts to the bottom source/drain, the gate conductor, and the top source/drain.

Abstract: In an exemplary method, a first dielectric layer is formed on a substrate. A second dielectric layer is formed on the first dielectric layer. The second dielectric layer is a carbon rich film and different from the first dielectric layer. A trench is formed through the first and second dielectric layers. A conductive line is formed in the trench. A third dielectric layer is formed on the second dielectric layer and conductive line. The material of the third dielectric layer is different from the second dielectric layer. A via opening is formed through the third dielectric layer and stops at the second dielectric layer with a portion of the conductive line exposed to the via opening. At the bottom of the via opening, a recess is formed in the second dielectric layer adjacent to the conductive line. The via opening and recess are filled with a conductive material contacting the conductive line.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to replacement metal gate structures and methods of manufacture. The structure includes at least one short channel device including a dielectric material, a workfunction metal, and a capping material, and a long channel device comprising the dielectric material, the workfunction metal and fluorine free gate conductor material.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to merged mandrel lines and methods of manufacture. The structure includes: at least one metal line having a first dimension in a self-aligned double patterning (SADP) line array; and at least one metal line having a second dimension inserted into the SADP line array, the second dimension being different than the first dimension.

Abstract: Structures for laterally-diffused metal-oxide-semiconductor devices and drain-extended metal-oxide-semiconductor devices, as well as methods of forming laterally-diffused metal-oxide-semiconductor devices and drain-extended metal-oxide-semiconductor devices. A gate electrode is arranged to extend about a semiconductor fin projecting from a substrate. A drain region is arranged in the substrate, and a source region is coupled with the semiconductor fin. The source region is arranged over the semiconductor fin. A drift region is arranged in the substrate between the drain region and the semiconductor fin. The drain region, source region, and drift region have a given conductivity type. The drift region has a lower electrical conductivity than the drain region.

Abstract: A sense amplifier includes, among other components, a first capacitor adapted to be charged to a precharge voltage, a complementary transistor pair (adapted to connect to the first capacitor, to a reference resistance device, and to a memory cell), a comparator adapted to connect to the complementary transistor pair, and a second capacitor adapted to connect to the comparator. The complementary transistor pair is adapted to produce a first bit voltage based on the precharge voltage and the reference resistance of the reference resistance device. The comparator is adapted to charge the second capacitor to a comparison voltage based on the first bit voltage. The complementary transistor pair is adapted to produce a cell bit voltage based on the precharge voltage and the resistance of the memory cell. The comparator is adapted to compare the cell bit voltage to the comparison voltage to produce an amplified memory cell value.

Abstract: Processes form integrated circuit apparatuses that include parallel fins, wherein the fins are patterned in a first direction. Parallel gate structures intersect the fins in a second direction perpendicular to the first direction, wherein the gate structures have a lower portion adjacent to the fins and an upper portion distal to the fins. Source/drain structures are positioned on the fins between the gate structures. Source/drain contacts are positioned on the source/drain structures and multiple insulator layers are positioned between the gate structures and the source/drain contacts. Additional upper sidewall spacers are positioned between the upper portion of the gate structures and the multiple insulator layers.

Abstract: This disclosure is directed to an integrated circuit (IC) structure. The IC structure may include a semiconductor substrate having a first fin and a second fin spaced from the first fin; a first source/drain region in the first fin, the first source/drain region encompassing a top surface and two opposing lateral sides of the first fin; a second source/drain region in the second fin, the second source/drain encompassing a top surface and two opposing lateral sides of the second fin; and a metal contact extending over the first source/drain region and the second source/drain region and surrounding the top surface and at least a portion of the two opposing lateral sides of each of the first and the second source/drain regions.

Abstract: A method for forming a self-aligned sacrificial epitaxial cap for trench silicide and the resulting device are provided. Embodiments include a Si fin formed in a PFET region; a pair of Si fins formed in a NFET region; epitaxial S/D regions formed on ends of the Si fins; a replacement metal gate formed over the Si fins in the PFET and NFET regions; metal silicide trenches formed over the epitaxial S/D regions in the PFET and NEFT regions; a metal layer formed over top surfaces of the S/D region in the PFET region and top and bottom surfaces of the S/D regions in the NFET region, wherein the epitaxial S/D regions in the PFET and NFET regions are diamond shaped in cross-sectional view.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to contact and interconnect structures and methods of manufacture. The structure includes: a single damascene contact structure in electrical contact with a contact of a source region or drain region; and a single damascene interconnect structure in a wiring layer and in direct electrical contact with the single damascene contact structure.

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 disclosure relates to gate-all-around (GAA) transistors with a spacer support, and related methods. A GAA transistor according to embodiments of the disclosure includes: at least one semiconductor channel structure extending between a source terminal and a drain terminal; a spacer support having a first portion thereof positioned underneath and a second portion thereof positioned alongside a first portion of the at least one semiconductor channel structure; and a gate metal surrounding a second portion of the at least one semiconductor channel structure between the source and drain terminals; wherein the spacer support is positioned between the gate metal and the source or drain terminal.

Abstract: Embodiments of the present disclosure provide a circuit structure including four FDSOI transistors coupled to a single output node at their respective back-gate terminals. An input voltage line may be coupled to the gate terminal of two transistors. The two transistors each may be coupled to the gate terminal of two other transistors at one of their source or drain terminals via a junction node. The other two transistors may be coupled to the single output node through one of their source or drain terminals. The other source or drain terminal of each transistor may be electrically coupled to a source voltage line or a drain voltage line.

Abstract: In the manufacture of a FinFET device, an isolation architecture is provided between gate and source/drain contact locations. The isolation architecture may include a low-k spacer layer and a contact etch stop layer. The isolation architecture further includes a high-k, etch-selective layer that is adapted to resist degradation during an etch to open the source/drain contact locations. The high-k layer, in conjunction with a self-aligned contact (SAC) capping layer disposed over the gate, forms an improved isolation structure that inhibits short circuits or parasitic capacitance between the gate and source/drain contacts.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to measurement circuits for logic paths and methods of manufacture. The circuit includes: a flip flop device outputting an output signal comprising an intrinsic delay; a logic path looping the output signal back to the flip flop device such that the intrinsic delay is to be received by the flip flop device; and an oscillator which feeds an input signal into the logic path and sweeps the input signal to alter the looped output signal thereby providing a maximum frequency of the logic path.

Abstract: Disclosed are embodiments of a system, method and computer program product for wafer-level design including chip and frame design. The embodiments employ three-dimensional (3D) emulation to preliminarily verify in-kerf optical macros included in a frame design layout. Specifically, 3D images of a given in-kerf optical macro at different process steps are generated by a 3D emulator and a determination is made as to whether or not that macro will be formed as predicted. If not, the plan for the macro is altered using an iterative design process. Once the in-kerf optical macros within the frame design layout have been preliminarily verified, wafer-level design layout verification, including chip and frame design layout verification, is performed. Once the wafer-level design layout has been verified, wafer-level design layout validation, including chip and frame design layout validation, is performed. Optionally, an emulation library can store results of 3D emulation processes for future use.

Abstract: A disclosed pre-driver includes multiple signal generation stages and a switching bias circuit with a first switch and a second switch. The first switch and primary inverters in each of the stages all receive the same input signal. When the input signal transitions, the first switch turns on the bias circuit to supply a bias voltage to each of the stages. However, the primary inverters do not concurrently turn on. Instead, due to the bias voltage and some additional circuitry within each stage, the primary inverters turn on in sequence and slowly, thereby ensuring that pre-driver signals generated and output by the different stages, respectively, transition in sequence and at a relatively slow rate. Once the last pre-driver signal transitions, the second switch turns off the switching bias circuit. Optionally, a selected one of multiple bias voltages could be used in order to tune delay and transition times.

Abstract: A repairable rigid test probe system includes an annular gimbal supported by an annular gimbal bearing of a probe card assembly, a test substrate seated and aligned within the annular gimbal, a rigid die including thick periphery and a thin center containing an array of through holes that is aligned above the test substrate, and an array of rigid probes inserted into each of the array of through holes, where each rigid probe includes: a tail end that contacts a connection on a facing surface of the test substrate, a collar limiting a distance of insertion, and a tip that contacts a corresponding contact on a facing surface of a device under test.