Abstract: A gate all around transistor may be improved to provide better transistor circuits performance. In one example, a transistor circuit may include a dielectric or air gap as an insulator between the channels of the transistors in the circuit. In another example, a transistor may include a first channel surrounded by a first metal, a second channel surrounded by a second metal proximate to the first channel, and an insulator, such as a dielectric or air gap, between the first metal and the second metal. The insulator helps reduce the parasitic capacitance between the source/drain regions and the metal fill regions of the transistor.

Abstract: Strained silicon transistor, such as GAA transistors, allow for both good PMOS mobility and NMOS mobility on the same substrate. In one example, a GAA circuit may include a NMOS device on a tensile strained Si channel and a PMOS device on a compressive strained SiGe channel. In another example, a GAA circuit may include a NMOS device on a strained Si channel and a PMOS device on a relaxed SiGe channel on (110) crystalline substrate.

Abstract: To prevent short defects between source/drains of transistors of a complementary cell circuit, isolation walls are formed in an isolation region between the source/drains of the transistors prior to growing a P-type epitaxial layer and an N-type epitaxial layer on respective sides of the isolation region. The isolation walls provide a physical barrier to prevent formation of short defects that can otherwise form between the P-type and N-type epitaxial layers. Thus, the isolation walls prevent circuit failures resulting from electrical shorts between source/drain regions of transistors in complementary cell circuits. A width of the isolation region between a P-type transistor and an N-type transistor in a circuit cell layout can be reduced so that a total layout area of the complementary cell circuit can be reduced without reducing product yield. A gate cut may be formed in the dummy gate with a process of forming the isolation walls.

Abstract: An input device for a multiple wavelength band optical switch comprising: an optical demultiplexer configured to receive light and disperse the received light along a dispersion axis; and a light director configured to direct light in a first wavelength band to the optical demultiplexer at a first angle of incidence and to direct light in a second wavelength band to the optical demultiplexer at a second angle of incidence, the second angle of incidence being different from the first; wherein the difference between the first and second angles of incidence causes the demultiplexer to output dispersed spectra of light corresponding to the first and second bands such that the dispersed spectrum corresponding to the first band is overlapped along the dispersion axis and separated along a switch axis relative to the dispersed spectrum corresponding to the second wavelength band, the switch axis being perpendicular to the dispersion axis.

Abstract: An optical switching unit comprising: a plurality of arrays of multiple optical waveguides; and a switching structure controllable to direct light received from any of the optical waveguides in a first array of the plurality of arrays to one or more optical waveguides of each other array in the plurality of arrays.

Abstract: A semiconductor device comprising an N-type metal oxide semiconductor (NMOS) gate-all-around (GAA) transistor and a P-type metal oxide semiconductor (PMOS) GAA transistor with high charge mobility channel materials is disclosed. The semiconductor device may include a substrate. The semiconductor device may also include an NMOS GAA transistor on the substrate, wherein the NMOS GAA transistor comprises a first channel material. The semiconductor device may further include a PMOS GAA transistor on the substrate, wherein the PMOS GAA transistor comprises a second channel material. The first channel material may have an electron mobility greater than an electron mobility of Silicon (Si) and the second channel material may have a hole mobility greater than a hole mobility of Si.

Abstract: Certain aspects of the present disclosure generally relate to a single diffusion break having a conductive portion. An example semiconductor device generally includes a first semiconductor region, a second semiconductor region, a dielectric region, and a single diffusion break (SDB). The dielectric region is disposed between the first semiconductor region and the second semiconductor region. The SDB intersects at least one of the first semiconductor region or the second semiconductor region, and the SDB comprises an electrically conductive portion.

Abstract: Certain aspects of the present disclosure are directed to a semiconductor device. The semiconductor device generally includes a substrate, at least one silicon-on-insulator (SOI) transistor disposed above the substrate, a gate-all-around (GAA) transistor disposed above the substrate, and a fin field-effect transistor (FinFET) disposed above the substrate.

Abstract: Certain aspects are directed to a static random access memory (SRAM) including an SRAM cell with a pass-gate (PG) transistor having increased threshold voltage to improve the read margin of the SRAM cell. The SRAM generally includes a first SRAM cell having a pull-down (PD) transistor and a PG transistor coupled to the PD transistor. In certain aspects, the SRAM includes a second SRAM cell, the second SRAM cell being adjacent to the first SRAM cell and having a PD transistor and a PG transistor coupled to the PD transistor of the second SRAM cell. The SRAM may also include a gate contact region coupled to a gate region of the PG transistor of the first SRAM cell, wherein at least a portion of the gate contact region is offset from a midpoint between the first SRAM cell and the second SRAM cell.

Abstract: A cell circuit includes a first power rail, having a first line length, in a first layer. The first power rail is configured to receive a first voltage for the cell circuit. The cell circuit includes multiple lines in a second layer and a shunt in a third layer. The shunt is electrically coupled to the first power rail and a first set of lines of the multiple lines. The shunt has a second line length shorter than the first line length. The cell circuit includes another shunt in t the third layer. The other shunt is also parallel to the first power rail. The other shunt is electrically coupled to the first power rail and a second set of lines of the multiple lines. The other shunt has a third line length shorter than the first line length.

Abstract: Circuits employing an adjacent low-k dummy gate to a field-effect transistor (FET) to reduce FET source/drain parasitic capacitance, and related fabrication methods. To reduce or mitigate an increase in the source/drain parasitic capacitance(s) of a FET, a dummy gate adjacent to an active gate of the FET is provided to have a low-k (i.e., low relative permittivity). In this manner, the relative permittivity (k) between the source/drain of the FET and an adjacent dummy gate and/or source/drain of another FET is reduced, thereby reducing the parallel plate capacitance of the FET(s). Reducing parasitic capacitance of the FET(s) may allow further reduced scaling of the circuit to offset or mitigate a lack of reduction or increase in parasitic capacitance as a result of reducing gate pitch in the circuit. As gate pitch is reduced in the circuit, it may not be possible to proportionally reduce gate size without sacrificing gate control.

Abstract: Certain aspects of the present disclosure generally relate to a semiconductor device with a gate-cut isolation structure. An example method of fabricating semiconductor device generally includes forming a dielectric region between a first semiconductor region and a second semiconductor region. The method also includes forming a first gate region disposed above and spanning a width of the dielectric region between the first and second semiconductor regions, wherein the first gate region is also disposed above at least a portion of the first semiconductor region and above at least a portion of the second semiconductor region. The method further includes concurrently forming an SDB and a gate-cut isolation structure, wherein the SDB intersects the first and second semiconductor regions and wherein the gate-cut isolation structure electrically separates the first gate region into a first portion associated with the first semiconductor region and a second portion associated with the second semiconductor region.

Abstract: Certain aspects of the present disclosure are directed to a semiconductor device. The semiconductor device generally includes a ferroelectric (FE) semiconductor device having a channel region; a gate oxide; a FE region, wherein the gate oxide is disposed between the FE region and the channel region; a gate region, wherein the FE region is disposed between the gate oxide and the gate region; a first semiconductor region disposed adjacent to the channel region; and a second semiconductor region disposed adjacent to the channel region. The semiconductor device may also include a transistor, wherein a region of the transistor is connected to the gate region, the first semiconductor region, or the second semiconductor region of the FE semiconductor device.

Abstract: We describe a space-division multiplexed (SDM) fibre, reconfigurable, wavelength-selective switch (WSS).

Abstract: Circuits employing on-diffusion (OD) edge (ODE) dummy gate structures in cell circuit with increased gate dielectric thickness to reduce leakage current are disclosed. A gate dielectric structure may be formed between a work function metal structure of an ODE dummy gate structure and an active semiconductor structure in a cell circuit, and is provided to be thicker than a gate dielectric structure formed between a work function metal structure and an active gate(s) in the cell circuit. Providing a gate dielectric structure of increased thickness can reduce damage to the gate dielectric structure providing isolation between the ODE dummy gate structure and the active semiconductor structure. Providing a gate dielectric structure of increased thickness can also reduce the gap area adjacent to the ends of the active semiconductor structures and thus reduce the volume of work function metal structure formed in the gaps to further reduce leakage current.

Abstract: Certain aspects of the present disclosure generally relate to a single diffusion break having a conductive portion. An example semiconductor device generally includes a first semiconductor region, a second semiconductor region, a dielectric region, and a single diffusion break (SDB). The dielectric region is disposed between the first semiconductor region and the second semiconductor region. The SDB intersects at least one of the first semiconductor region or the second semiconductor region, and the SDB comprises an electrically conductive portion.

Abstract: Certain aspects of the present disclosure generally relate to a static random-access memory (SRAM) implemented using both a gate-all-around (GAA)-type transistor and a fin field-effect transistor (FinFET). For example, certain aspects are directed to an SRAM memory cell having a flip-flop (FF) having a pull-up (PU) transistor and a pull-down (PD) transistor, and a pass-gate (PG) transistor coupled between a bit line of the SRAM memory cell and the FF, a gate of the PG transistor being coupled to a word line (WL) of the SRAM memory cell. In certain aspects, at least one of the PU transistor, the PD transistor, or the PG transistor comprises a GAA transistor, and at least another one of the PU transistor, the PD transistor, or the PG transistor comprises a FinFET.

Abstract: A spatial phase modulator and a method for producing a spatial phase modulator are provided. The spatial phase modulator includes a first substrate and a second substrate that are meshed together, and a liquid crystal layer disposed between the two substrates, where a transparent electrode layer and a first alignment and guiding layer are disposed in a cascading manner on a side that is of the first substrate and that faces the liquid crystal layer; and an electrode layer and an insulation medium glass layer are disposed in a cascading manner on a side that is of the second substrate and that faces the liquid crystal layer, where the insulation medium glass layer has an inclined serration structure on a side facing the liquid crystal layer.

Abstract: A semiconductor device is disclosed that includes a plurality of fins on a substrate. A long channel gate is disposed over a first portion of the plurality of fins. A gate contact is provided having an extended portion that extends into an active area from a gate contact base outside the active area.

Abstract: Certain aspects of the present disclosure generally relate to an integrated device including a low parasitic middle-of-line (MOL) structure. The integrated device generally includes a plurality of semiconductor devices; an MOL structure disposed above the plurality of semiconductor devices and comprising a dielectric layer; a first barrier-less conductor extending between a first terminal of a semiconductor device in the plurality of semiconductor devices and into the MOL structure; and a first air gap disposed between a lateral surface of an upper portion of the first barrier-less conductor and the dielectric layer of the MOL structure.