Abstract: Disclosed is a photonic integrated circuit having a plurality of lenses and a method for making the same. The photonic integrated circuit is comprised of optical circuitry fabricated over an underlying circuitry layer. In some embodiments, the optical circuitry includes a dielectric material having recesses disposed within, layers of a light waveguide material deposited within the recesses, and lenses disposed over each layer of waveguide material. The underlying circuitry layer may include, for example, a semiconductor wafer as well as circuitry fabricated during front end of line (FEOL) semiconductor manufacturing such as, for example, sources, gates, drains, interconnects, contacts, resistors, and other circuitry that may be manufactured during FEOL processes. The underlying circuitry layer may also include circuitry manufactured during back end of line semiconductor manufacturing processes such as, for example, interconnect structures, metallization layers, and contacts.

Abstract: A method for making a semiconductor device may include forming, above a substrate, a plurality of fins, forming a first semiconductor material on sides of a first group of the fins, and forming a second semiconductor material on sides of a second group of the fins. The method may further include forming a dielectric layer overlying the plurality of fins to define first and second groups of nanowires within the dielectric layer, with the first group of nanowires including the first semiconductor material and the second group of nanowires including the second semiconductor material.

Abstract: A method for making a semiconductor device may include forming, above a substrate, a stack of alternating layers of first and second semiconductor materials. The second semiconductor material may be different than the first semiconductor material. The method may further include forming fins from the stack, with each fin having alternating layers of the first and second semiconductor materials, and selectively removing sidewall portions of the second semiconductor material from the fins to define recesses therein. The method may also include forming a dielectric material within the recesses, forming additional first semiconductor material on sidewall portions of the first semiconductor material in the fins, and forming a dielectric layer overlying the fins to define nanowires including the first semiconductor material within the dielectric layer.

Abstract: The presence of a child within an enclosed space in an appliance, such as a washing machine, dishwasher or refrigerator, is detected using one or more MEMS sensors positioned to detect movement within the enclosed space through various measured characteristics. In preference, combinations of different types of MEMS sensors are utilized to detect the movement. Movement may be attributed to the presence of a child inside the enclosed space, rather than resulting from other influences, with increased reliability if the determination is made based upon such combinations of different characteristics. Safety processes may be initiated upon detecting the presence of the child.

Abstract: A structure having a diffusion barrier positioned adjacent to a sidewall and a bottom of an opening being etched in a layer of dielectric material. The structure also having a metal liner positioned directly on top of the diffusion barrier, a seed layer positioned directly on top of the metal liner, wherein the seed layer is made from a material comprising copper, a copper material positioned directly on top of the seed layer, a metallic cap positioned directly on top of and selective to the copper material, and a capping layer positioned directly on top of and adjacent to the metallic cap.

Abstract: Integrated circuit devices and fabrication techniques. A semiconductor device fabrication method may include doping, in a same processing step, first and second portions of a substrate of an integrated circuit. The first portion corresponds to a doped region of a semiconductor device. The second portion corresponds to a via contact. The method may further include, after the doping, forming the gate of the semiconductor device.

Abstract: A method is for making a semiconductor device. The method may include forming fins above a substrate, each fin having an upper fin portion including a first semiconductor material and a lower fin portion including a dielectric material. The method may include forming recesses into sidewalls of each lower fin portion to expose a lower surface of a respective upper fin portion, and forming a second semiconductor layer surrounding the fins including the exposed lower surfaces of the upper fin portions. The second semiconductor layer may include a second semiconductor material to generate stress in the first semiconductor material.

Abstract: Transistors having partially recessed gates are constructed on silicon-on-insulator (SOI) semiconductor wafers provided with a buried oxide layer (BOX), for example, FD-SOI and UTBB devices. An epitaxially grown channel region relaxes constraints on the design of doped source and drain profiles. Formation of a partially recessed gate and raised epitaxial source and drain regions allow further improvements in transistor performance and reduction of short channel effects such as drain induced barrier lowering (DIBL) and control of a characteristic subthreshold slope. Gate recess can be varied to place the channel at different depths relative to the dopant profile, assisted by advanced process control. The partially recessed gate has an associated high-k gate dielectric that is initially formed in contact with three sides of the gate. Subsequent removal of the high-k sidewalls and substitution of a lower-k silicon nitride encapsulant lowers capacitance between the gate and the source and drain regions.

Abstract: Methods and structures for forming highly-doped, ultrathin layers for transistors formed in semiconductor-on-insulator substrates are described. High dopant concentrations may be achieved in ultrathin semiconductor layers to improve device characteristics. Ion implantation at elevated temperatures may mitigate defect formation for stoichiometric dopant concentrations up to about 30%. In-plane stressors may be formed adjacent to channels of transistors formed in ultrathin semiconductor layers.

Abstract: A stack of an interlevel dielectric (ILD) layer, a dielectric cap layer, and a metallic hard mask layer is formed on a substrate. The metallic hard mask layer can be patterned with a first pattern. A photoresist layer is formed over the metallic hard mask layer and is patterned with a second pattern. A combination of the first pattern and the second pattern is transferred into the ILD layer to form a dual damascene trench, which includes an undercut underneath the patterned dielectric cap layer. The metallic hard mask layer is removed and the dielectric cap layer is anisotropically etched to form faceted edges and removal of overhanging portions. A metallic material can be deposited into the dual damascene trench without formation of voids during a metal fill process.

Abstract: A method for forming a complementary metal oxide semiconductor (CMOS) semiconductor device includes forming laterally adjacent first and second active regions in a semiconductor layer of a silicon-on-insulator (SOI) wafer. A stress inducing layer is formed above the first active region to impart stress thereto. Trench isolation regions are formed bounding the first active region and adjacent portions of the stress inducing layer. The stress inducing layer is removed leaving the trench isolation regions to maintain stress imparted to the first active region.

Abstract: Metal interconnections are formed in an integrated circuit by forming a wide trench in a dielectric layer. A dielectric fin of a second dielectric material is formed in the trench. Conductive plugs and metal lines are formed on both sides of the fin.

Abstract: Methods and structures for forming strained-channel finFETs are described. Fin structures for finFETs may be formed using two epitaxial layers of different lattice constants that are grown over a bulk substrate. A first thin, strained, epitaxial layer may be cut to form strain-relieved base structures for fins. The base structures may be constrained in a strained-relieved state. Fin structures may be epitaxially grown in a second layer over the base structures. The constrained base structures can cause higher amounts of strain to form in the epitaxially-grown fins than would occur for non-constrained base structures.

Abstract: On a substrate formed of a first semiconductor material, a first overlying layer formed of a second semiconductor material is deposited. A second overlying layer formed of a third semiconductor material is deposited over the first overlying layer. The first and second overlying layers are patterned to define fins, wherein each fin includes a first region formed of the third material over a second region formed of the second material. An oxide material fills the space between the fins. A thermal oxidation is then performed to convert the second region to a material insulating the first region formed of the third material from the substrate. As an optional step, the second region formed of the second material is horizontally thinned before the oxide material is deposited and the thermal oxidation is performed. Once the fins are formed and insulated from the substrate, conventional FinFET fabrication is performed.

Abstract: The present disclosure generally provides for a method of forming a FinFET with a silicon germanium (SiGe) stressor, in addition to a FinFET structure obtained from embodiments of the method. The method can include forming a semiconductor fin on a buried insulator layer; forming a gate structure on the semiconductor fin; forming a silicon germanium (SiGe) layer on the buried insulator layer, wherein the SiGe layer contacts the semiconductor fin; and heating the SiGe layer, wherein the heating diffuses germanium (Ge) into the semiconductor fin.

Abstract: Semiconductor fabrication methods are provided which include facilitating fabricating semiconductor fin structures by: providing a wafer with at least one fin extending above a substrate, the at least one fin including a first layer disposed above a second layer; mechanically stabilizing the first layer; removing at least a portion of the second layer of the fin(s) to create a void below the first layer; filling the void, at least partially, below the first layer with an isolation material to create an isolation layer within the fin(s); and proceeding with forming a fin device(s) of a first architectural type in a first fin region of the fin(s), and a fin device(s) of a second architectural type in a second fin region of the fin(s), where the first architectural type and the second architectural type are different fin device architectures.

Abstract: A multi-fin FINFET device may include a substrate and a plurality of semiconductor fins extending upwardly from the substrate and being spaced apart along the substrate. Each semiconductor fin may have opposing first and second ends and a medial portion therebetween, and outermost fins of the plurality of semiconductor fins may comprise an epitaxial growth barrier on outside surfaces thereof. The FINFET may further include at least one gate overlying the medial portions of the semiconductor fins, a plurality of raised epitaxial semiconductor source regions between the semiconductor fins adjacent the first ends thereof, and a plurality of raised epitaxial semiconductor drain regions between the semiconductor fins adjacent the second ends thereof.

Abstract: A method of making a semiconductor device includes forming an intermediate structure including second semiconductor fin portions above a first semiconductor layer, and top first semiconductor fin portions extending from respective ones of the second semiconductor fin portions. The second semiconductor fin portions are selectively etchable with respect to the top first semiconductor fin portions. A dummy gate is on the intermediate structure. The second semiconductor fin portions are selectively etched to define bottom openings under respective ones of the top first semiconductor fin portions. The bottom openings are filled with a dielectric material.

Abstract: An embodiment of a transmitter includes detection, generating, and transmission stages. The detection stage is configured to detect a first signal having a first component that includes a frequency, and the generating stage is configured to generate a data component that includes approximately the frequency in response to the detection of the first signal. The transmission stage is configured to transmit a second signal having the data component while the detection stage is detecting the first signal. For example, two or more such transmitters (e.g., two or more smart phones) may simultaneously transmit OFDM signals on the same subcarrier frequencies and over the same channel space. By allowing the simultaneous transmission of multiple signals on the same frequencies and over the same channel space, such a transmitter may increase the effective bandwidth of the channel space, and thus may allow more devices to simultaneously share the same channel space.

Abstract: A USB mass storage device includes a memory, USB interface and USB controller. A biometric circuit provides biometric authentication and a secure microcontroller is operatively connected to the biometric circuit and the USB controller and operative in accordance as a trusted platform and having a command set to access security functions and trust authentication of a user using the biometric circuit.