Abstract: Techniques are provided for alerting drivers of hazardous driving conditions using the sensing capabilities of wearable mobile technology. In one aspect, a method for alerting drivers of hazardous driving conditions includes the steps of: collecting real-time data from a driver of a vehicle, wherein the data is collected via a mobile device worn by the driver; determining whether the real-time data indicates that a hazardous driving condition exists; providing feedback to the driver if the real-time data indicates that a hazardous driving condition exists, and continuing to collect data from the driver in real-time if the real-time data indicates that a hazardous driving condition does not exist. The real-time data may also be collected and used to learn characteristics of the driver. These characteristics can be compared with the data being collected to help determine, in real-time, whether the driving behavior is normal and whether a hazardous driving condition exists.

Abstract: Techniques for modifying user behavior and screening for impairment using a mobile feedback controller, such as a smartwatch, are provided. In one aspect, a method for monitoring a user includes the steps of: collecting real-time data from the user, wherein the data is collected via a mobile feedback controller worn by the user; determining whether the data collected from the user indicates impairment; determining appropriate corrective actions to be taken if the data collected from the user indicates impairment, otherwise continuing to collect data from the user in real-time; determining whether any action is needed; and undertaking the appropriate corrective actions if action is needed, otherwise continuing to collect data from the user in real-time.

Abstract: A semiconductor device is provided and includes first and second dielectrics, first and second conductive elements, a self-formed-barrier (SFB) and a liner. The first and second dielectrics are disposed with one of first-over-second dielectric layering and second-over-first dielectric layering. The first and second conductive elements are respectively suspended at least partially within a lower one of the first and second dielectrics and at least partially within the other one of the first and second dielectrics. The self-formed-barrier (SFB) is formed about a portion of one of the first and second conductive elements which is suspended in the second dielectric. The liner is deposited about a portion of the other one of the first and second conductive elements which is partially suspended in the first dielectric.

Abstract: A system and method perform remote physical training. The method includes receiving movements performed by an operator who is remotely located, and presenting the movements of the operator as movements performed by an avatar representing the operator in a virtual reality environment. The method also includes remotely monitoring the movements of the avatar, and providing real-time feedback on the movements to the operator.

Abstract: A method is presented for forming a semiconductor structure. The method includes depositing a barrier layer, such as a tantalum nitride (TaN) layer, over a dielectric incorporating magnetic random access memory (MRAM) regions, forming magnetic tunnel junction (MTJ) stacks over portions of the TaN layer, patterning and encapsulating the MTJ stacks, forming spacers adjacent the MTJ stacks, and laterally etching sections of the TaN layer, after spacer formation, to form an electrode under the MTJ stacks. The electrode protects the MRAM regions. The electrode can be recessed from the spacers.

Abstract: A method of forming a semiconductor device, includes forming a conductive layer in a recessed portion of a porous dielectric layer, partially removing a top portion of the conductive layer while maintaining a height of the porous dielectric layer, forming a conformal cap layer on the porous dielectric layer and the conductive layer in the recessed portion, polishing the conformal cap layer to form a gap in the conformal cap layer, such that an upper surface of the porous dielectric layer is exposed through the gap and an upper surface of the conductive layer is protected by the cap layer, and performing a heat treatment to burn out a pore filler of the porous dielectric layer through the exposed upper surface of the porous dielectric layer.

Abstract: A semiconductor structure includes a dielectric layer having a trench formed therein and a barrier layer formed on a bottom and sidewalls of the trench, and on a top surface of the dielectric layer. The trench comprises a flared top gap opening and additional area at the bottom such that the top and bottom of the trench are wider than sidewalls of the trench. A thickness of the barrier layer on the bottom of the trench and on the top surface of the dielectric layer is controlled using one or more cycles comprising forming an oxidized layer using a neutral beam oxidation and removing the oxidized layer using an etching process, such that the thickness of the barrier layer on the bottom of the trench and on the top surface of the dielectric layer is substantially the same as the thickness of the barrier layer on sidewalls of the trench.

Abstract: Multi-angled deposition and masking techniques are provided to enable custom trimming and selective removal of spacers that are used for patterning features at sub-lithographic dimensions. For example, a method includes forming a sacrificial mandrel on a substrate, and forming first and second spacers on opposing sidewalls of the sacrificial mandrel. The first and second spacers are formed with an initial thickness TS. A first angle deposition process is performed to deposit a material (e.g., insulating material or metallic material) at a first deposition angle A1 to form a first trim mask layer on an upper portion of the first spacer and the sacrificial mandrel while preventing the material from being deposited on the second spacer. A spacer etch process is performed to trim the first spacer to a first thickness T1, which is less than TS, using the first trim mask layer as an etch mask.

Abstract: A semiconductor device includes a porous dielectric layer formed on an interconnect layer and including a recessed portion, a conductive layer formed in the recessed portion, and a conformal cap layer formed on the porous dielectric layer and on the conductive layer in the recessed portion, an upper surface of the porous dielectric layer being exposed through a gap in the conformal cap layer. Porous dielectric material is protected by back-filled pore fillers or leave-in porogens from process integration such as chemical mechanical polishing (CMP). The pore fillers or porogens are removed after CMP and Cap process to achieve low capacitance. A self-aligned cap protects the conductor metal from exposing the severe conditions during the pore filler or porogen removal process.

Abstract: A method for via alignment includes forming first airgaps between interconnect structures and depositing a pinch off layer to close off openings to the first airgaps. A protection layer is formed in divots in the pinch off layer. The protection layer and the pinch off layer are planarized to form a surface where the protection layer remains in the divots. An interlevel dielectric layer (ILD) is deposited on the surface. The ILD and the pinch off layer are etched using the protection layer as an etch stop to align a via and expose the interconnect structure through the via.

Abstract: A method for providing a uniform recess depth between different fin gap sizes includes depositing a dielectric material between fins on a substrate. Etch lag is tuned for etching the dielectric material between narrow gaps faster than the dielectric material between wider gaps such that the dielectric material in the narrow gaps reaches a target depth. An etch block is formed in the narrow gaps. The wider gaps are etched to the target depth. The etch block is removed.

Abstract: Techniques for preventing switching of spins in a magnetic tunnel junction by stray magnetic fields using a thin film magnetic shield are provided. In one aspect, a method of forming a magnetic tunnel junction includes: forming a stack on a substrate, having a first magnetic layer, a tunnel barrier, and a second magnetic layer; etching the stack to partially pattern the magnetic tunnel junction in the stack, wherein the etching includes patterning the magnetic tunnel junction through the second magnetic layer, the tunnel barrier, and partway through the first magnetic layer; depositing a first spacer and a magnetic shield film onto the partially patterned magnetic tunnel junction; etching back the magnetic shield film and first spacer; complete etching of the magnetic tunnel junction through the first magnetic layer to form a fully patterned magnetic tunnel junction; and depositing a second spacer onto the fully patterned magnetic tunnel junction.

Abstract: A method of forming a semiconductor structure includes forming at least one trench in a dielectric layer, forming a barrier layer on a bottom of said at least one trench, sidewalls of said at least one trench and a top surface of the dielectric layer, the barrier layer having a non-uniform thickness, and selectively thinning at least a first portion of the barrier layer using one or more cycles comprising forming an oxidized layer in the first portion of the barrier layer using a neutral beam oxidation and removing the oxidized layer using an etching process.

Abstract: A method for providing a uniform recess depth between different fin gap sizes includes depositing a dielectric material between fins on a substrate. Etch lag is tuned for etching the dielectric material between narrow gaps faster than the dielectric material between wider gaps such that the dielectric material in the narrow gaps reaches a target depth. An etch block is formed in the narrow gaps. The wider gaps are etched to the target depth. The etch block is removed.

Abstract: A wafer is provided. The wafer includes a dielectric layer, first and second metallization layer interconnects arrayed across the dielectric layer with the second metallization layer interconnects adjacent one another and surrounded by the first metallization layer interconnects and a cap. The first and second metallization layer interconnects have respective upper surfaces defining a first plane and a second plane recessed from the first plane, respectively. The cap is disposed on exposed surfaces of the second metallization layer interconnects and portions of the dielectric layer adjacent to the second metallization layer interconnects.

Abstract: A method of forming a skip-via, including, forming a first dielectric layer on a first metallization layer, forming a second metallization layer on the first dielectric layer and a second dielectric layer on the second metallization layer, removing a section of the second dielectric layer to form a via to the second metallization layer, removing a portion of the second metallization layer to form an aperture, and removing an additional portion of the second metallization layer to form an exclusion zone.

Abstract: A field emission transistor includes a gate, a fold over emitter, and fold over collector. The emitter and the collector are separated from the gate by a void and are separated from a gate contact by gate contact dielectric. The void may be a vacuum, ambient air, or a gas. Respective ends of the emitter and the collector are separated by a gap. Electrons are drawn across gap from the emitter to the collector by an electrostatic field created when a voltage is applied to the gate. The emitter and collector include a first conductive portion substantially parallel with gate and a second conductive portion substantially perpendicular with gate. The second conductive portion may be formed by bending a segment of the first conductive portion. The second conductive portion is folded inward from the first conductive portion towards the gate. Respective second conductive portions are generally aligned.

Abstract: A method for providing a uniform recess depth between different fin gap sizes includes depositing a dielectric material between fins on a substrate. Etch lag is tuned for etching the dielectric material between narrow gaps faster than the dielectric material between wider gaps such that the dielectric material in the narrow gaps reaches a target depth. An etch block is formed in die narrow gaps. The wider gaps are etched to the target depth. The etch block is removed.

Abstract: A field emission transistor includes a gate, a fold over emitter, and fold over collector. The emitter and the collector are separated from the gate by a void and are separated from a gate contact by gate contact dielectric. The void may be a vacuum, ambient air, or a gas. Respective ends of the emitter and the collector are separated by a gap. Electrons are drawn across gap from the emitter to the collector by an electrostatic field created when a voltage is applied to the gate. The emitter and collector include a first conductive portion substantially parallel with gate and a second conductive portion substantially perpendicular with gate. The second conductive portion may be formed by bending a segment of the first conductive portion. The second conductive portion is folded inward from the first conductive portion towards the gate. Respective second conductive portions are generally aligned.

Abstract: Methods are provided for fabricating metallic interconnect structures having reduced electrical resistivity that is obtained by applying mechanical strain to the metallic interconnect structures, as well as semiconductor structures having metallic interconnect structures formed with permanent mechanical strain to provide reduced electrical resistivity. For example, a method includes forming a metallic interconnect structure in an interlevel dielectric (ILD) layer of a back-end-of-line (BEOL) structure of a semiconductor structure, and forming a stress layer in contact with the metallic interconnect structure. A thermal anneal process is performed to cause the stress layer to expand and apply compressive strain to the metallic interconnect structure and permanently deform at least a portion of the metallic interconnect structure into a stress memorized state of compressive strain.