Abstract: Embodiments in accordance with the present disclosure are directed to apparatuses used for reaction screening and optimization purposes. An example apparatus includes a plurality of reaction vessels, a dispensing subsystem, at least one reactor module, an analysis subsystem, an automation subsystem, and control circuitry. The dispensing subsystem delivers reagents to the plurality of reaction vessels for a plurality of reaction mixtures having varied reaction conditions. The at least one reactor module drives a plurality of reactions within the plurality of reaction vessels. The analysis subsystem analyzes compositions contained in the plurality of reaction vessels. The automation subsystem selectively moves the plurality of reaction vessels from a location proximal to the dispensing subsystem to the at least one reactor module based on experimental design parameters. And, the control circuitry identifies optimum reaction conditions for a target end product based on the analysis.

Abstract: A stand light includes an elongate body defining a longitudinal axis, a collar coupled to the elongate body for movement along the elongate body between a first position and a second position, and a plurality of legs coupled to the collar, the plurality of legs being collapsed against the elongate body when the collar is in the first position and being expanded apart from the elongate body when the collar is in the second position. The stand light also includes a head assembly coupled to an end of the elongate body. The head assembly includes a hub and a plurality of light heads. The hub is pivotably coupled to the end of the elongate body to pivot about a first pivot axis. Each of the plurality of light heads is pivotably coupled to the hub to pivot about a second pivot axis.

Abstract: Devices and systems for insulating integrated circuits from ultraviolet (“UV”) light are described. The device includes a conductive feature, a first and second UV blocking layer, a first and second insulating laver, and a conductive structure. The first insulating layer overlays the first UV blocking layer. A via opening extends through the first insulating layer and the first UV blocking layer. The second UV blocking layer overlays the first insulating laver. The second insulating layer overlays the second UV blocking layer. An interconnect trench is defined in the second insulating layer and second UV blocking layer. The conductive structure is electrically connected to the conductive feature and extends into the via opening and along the interconnect trench.

Abstract: An electronic device can include a conductive feature and an ultraviolet (“UV”) blocking layer overlying the conductive feature. The electronic device can also include an insulating layer overlying the UV blocking layer. The electronic device can further include a conductive structure extending into an opening within the insulating layer, wherein the conductive structure is electrically connected to the conductive feature. In one aspect, the UV blocking layer lies within 90 nm of the conductive structure. The insulating layer can be at least 4 times thicker than the UV blocking layer. In another aspect, a method can be used in forming the electronic device. In still a further aspect, a system can include the electronic device, a processor, and a display, wherein the processor is electrically coupled to the electronic device and the display.

Abstract: A process of forming an electronic device including forming a first ultraviolet (“UV”) blocking layer over a conductive feature, wherein the first UV blocking layer lies within 90 nm of the conductive structure; forming a first insulating layer over the first UV blocking layer; and patterning the first insulating layer and the first UV blocking layer to form a first opening extending to the conductive feature, wherein during the process, the first UV blocking layer is exposed to UV radiation.

Abstract: A metal strip casting apparatus and a method of casting continuous metal strip includes assembling a pair of counter-rotatable casting rolls having casting surfaces positioned laterally forming a nip between for casting, and delivering molten metal through a delivery nozzle disposed above the nip capable to form a casting pool supported on the casting rolls. The delivery nozzle comprises segments each having elongate nozzle body with longitudinally extending side walls, end walls and a bottom part to form an inner trough, a nozzle insert disposed above bottom portions of the inner trough of each segment and supported relative to the nozzle body through which incoming molten metal may be delivered to the inner trough of each segment of the delivery nozzle, and the elongate nozzle body of each segment having passageways in fluid communication with the inner trough and outlet openings capable of discharging molten metal from the nozzle body outwardly into the casting pool.

Abstract: An electronic device can include a conductive feature and an ultraviolet (“UV”) blocking layer overlying the conductive feature. The electronic device can also include an insulating layer overlying the UV blocking layer. The electronic device can further include a conductive structure extending into an opening within the insulating layer, wherein the conductive structure is electrically connected to the conductive feature. In one aspect, the UV blocking layer lies within 90 nm of the conductive structure. The insulating layer can be at least 4 times thicker than the UV blocking layer. In another aspect, a method can be used in forming the electronic device. In still a further aspect, a system can include the electronic device, a processor, and a display, wherein the processor is electrically coupled to the electronic device and the display.

Abstract: A metal strip casting apparatus and a method of casting continuous metal strip includes assembling a pair of counter-rotatable casting rolls having casting surfaces positioned laterally forming a nip between for casting, and delivering molten metal through a delivery nozzle disposed above the nip capable to form a casting pool supported on the casting rolls. The delivery nozzle comprises segments each having elongate nozzle body with longitudinally extending side walls, end walls and a bottom part to form an inner trough, a nozzle insert disposed above bottom portions of the inner trough of each segment and supported relative to the nozzle body through which incoming molten metal may be delivered to the inner trough of each segment of the delivery nozzle, and the elongate nozzle body of each segment having passageways in fluid communication with the inner trough and outlet openings capable of discharging molten metal from the nozzle body outwardly into the casting pool.

Abstract: An automotive engine oil pump assembly having first and second pump mechanisms contained within a common housing. A shaft rotatably supported in the housing drives the pump mechanisms in a conventional manner. The pump mechanisms are offset in phase to reduce flow pulsations through the housing and limit pump noise and vibration. The first pump mechanism communicates with a common inlet and first outlet of the housing. The second pump mechanism communicates with the common inlet and second outlet of the housing. A common reservoir connected to inlets of the first and second oil pump mechanisms provides a supplemental oil source to balance oil pressures at the pump inlets to prevent pump cavitation and further reduce pump noise and vibration.