Abstract: A workpiece alignment system is provided has a light emission apparatus that directs a light beam at a plurality of wavelengths along a path at a shallow angle toward a first side of a workpiece plane at a peripheral region. A light receiver apparatus, receives the light beam on a second side opposite the first side. A rotation device selectively rotates a workpiece support. According controller determines a position of the workpiece based on an amount of the light beam received through the workpiece when the workpiece intersects the path. A sensitivity of the light receiver apparatus is controlled based on a transmissivity of the workpiece. A position of the workpiece is determined when the workpiece is rotated based on the rotational position, an amount of the light beam received, the transmissivity of the workpiece, detection of a workpiece edge, and the controlled sensitivity of the light receiver apparatus.

Abstract: A system and method is provided maintaining a temperature of a workpiece during an implantation of ions in an ion implantation system, where the ion implantation system is characterized with a predetermined set of parameters. A heated chuck is provided at a first temperature and heats the workpiece to the first temperature. Ions are implanted into the workpiece concurrent with the heating, and thermal energy is imparted into the workpiece by the ion implantation. A desired temperature of the workpiece is maintained within a desired accuracy during the implantation of ions by selectively heating the workpiece on the heated chuck to a second temperature. The desired temperature is maintained based, at least in part, on the characterization of the ion implantation system. Thermal energy imparted into the workpiece from the implantation is mitigated by the selective heating of the workpiece on the heated chuck at the second temperature.

Abstract: A locking system that has an opening in a door adapted and arranged for receiving a lock bolt and a lock fixed in a wall for actuating a lock bolt adapting and arranged for being received by the opening in the door when the door is closed. Alternatively, the locking system is mounted on the exterior of the detention cell door and the adjacent exterior cell wall. The locking system further comprises a blocking strip protruding from a door jamb, the strip coupled to the door jamb, the strip coupled to the door jamb and positioned adjacent the lock bolt for blocking access to the lock bolt between the door and the door jamb. The locking system further comprises a system for monitoring and reporting the status of a detention cell door, the lock bolt, and the roller bolt.

Abstract: A heated chuck for an ion implantation system selectively clamps a workpiece to a carrier plate having heaters to selectively heat a clamping surface. A gap between a base plate and carrier plate of the heated chuck contains a heat transfer media. A cooling fluid source is coupled to cooling channels in the base plate. A controller operates the heated chuck in a first mode and second mode. In the first mode, the controller does not activate the heaters and flows the cooling fluid through the cooling channel, where heat is transferred through the heat transfer media and to the cooling fluid. In the second mode, the controller activates the heaters and optionally purges the cooling fluid from the cooling channel or otherwise alters its cooling capacity. A gas can be selectively provided in the gap to further control heat transfer in the first and second modes.

Abstract: An ion implantation system has a process chamber having a process environment, and an ion implantation apparatus configured to implant ions into a workpiece supported by a chuck within the process chamber. A load lock chamber isolates the process (vacuum) environment from an atmospheric environment, wherein a load lock workpiece support supports the workpiece therein. An isolation chamber is coupled to the process chamber with a pre-implant cooling environment defined therein. An isolation gate valve selectively isolates the pre-implant cooling environment from the process environment wherein the isolation chamber comprises a pre-implant cooling workpiece support for supporting and cooling the workpiece. The isolation gate valve is the only access path for the workpiece to enter and exit the isolation chamber. A pressurized gas selectively pressurizes the pre-implant cooling environment to a pre-implant cooling pressure that is greater than the process pressure for expeditious cooling of the workpiece.

Abstract: An ion implantation system has a process chamber having a process environment, and an ion implantation apparatus configured to implant ions into a workpiece supported by a chuck within the process chamber. A load lock chamber isolates the process (vacuum) environment from an atmospheric environment, wherein a load lock workpiece support supports the workpiece therein. An isolation chamber is coupled to the process chamber with a pre-implant cooling environment defined therein. An isolation gate valve selectively isolates the pre-implant cooling environment from the process environment wherein the isolation chamber comprises a pre-implant cooling workpiece support for supporting and cooling the workpiece. The isolation gate valve is the only access path for the workpiece to enter and exit the isolation chamber. A pressurized gas selectively pressurizes the pre-implant cooling environment to a pre-implant cooling pressure that is greater than the process pressure for expeditious cooling of the workpiece.

Abstract: An ion implantation system has an ion implantation apparatus coupled to first and second dual load lock assemblies, each having a respective first and second chamber separated by a common wall. Each first chamber has a pre-heat apparatus configured to heat a workpiece to a first temperature. Each second chamber has a post-cool apparatus configured to cool the workpiece to a second temperature. A thermal chuck retains the workpiece in a process chamber for ion implantation, and the thermal chuck is configured to heat the workpiece to a third temperature. A pump and vent are in selective fluid communication with the first and second chambers.

Abstract: An ion implantation system has an ion implantation apparatus coupled to first and second dual load lock assemblies, each having a respective first and second chamber separated by a common wall. Each first chamber has a pre-heat apparatus configured to heat a workpiece to a first temperature. Each second chamber has a post-cool apparatus configured to cool the workpiece to a second temperature. A thermal chuck retains the workpiece in a process chamber for ion implantation, and the thermal chuck is configured to heat the workpiece to a third temperature. A pump and vent are in selective fluid communication with the first and second chambers.

Abstract: An application programming interface is provided that allows applications to assign multiple service-level agreements to their data transactions. The service-level agreements include latency bounds and consistency guarantees. The applications may assign utility values to each of the service-level agreements. A monitor component monitors the various replica nodes in a cloud storage system for latency and consistency, and when a transaction is received from an application, the monitor determines which of the replica nodes can likely fulfill the transaction in satisfaction of any of the service-level agreements. Where multiple service-level agreements can be satisfied, the replica node that can fulfill the transaction according to the service-level agreement with the greatest utility is selected. The application may be charged for the transaction based on the utility of the service-level agreement that was satisfied.

Abstract: An application programming interface is provided that allows applications to assign multiple service-level agreements to their data transactions. The service-level agreements include latency bounds and consistency guarantees. The applications may assign utility values to each of the service-level agreements. A monitor component monitors the various replica nodes in a cloud storage system for latency and consistency, and when a transaction is received from an application, the monitor determines which of the replica nodes can likely fulfill the transaction in satisfaction of any of the service-level agreements. Where multiple service-level agreements can be satisfied, the replica node that can fulfill the transaction according to the service-level agreement with the greatest utility is selected. The application may be charged for the transaction based on the utility of the service-level agreement that was satisfied.

Abstract: A manifold and distribution manifold assembly is described for use in dividing the flow of an air-entrained material from a primary distribution line into a plurality of secondary distribution lines. The manifold is formed of a single molded piece thereby reducing the overall tooling cost. One application of such a distribution manifold assembly is in an air seeder.

Abstract: A lid for a distribution manifold is described where the manifold has an inlet opening defining an axis, access opening opposite the inlet and a plurality of radially extending outlet ports. The lid for the access opening includes a mounting member adapted to couple the lid to the manifold to close the access opening, a cone coupled to the mounting member and extending axially toward the inlet opening of the manifold when the lid is coupled to the manifold, and a single piece retainer adapted to secure the cone to the mounting member without additional fasteners.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth; distilling the broth under super atmospheric pressure at a temperature of >100° C. to about 300° C. to form an overhead that includes water and ammonia, and a liquid bottoms that includes SA, and at least about 20 wt % water; cooling the bottoms to a temperature sufficient to cause the bottoms to separate into a liquid portion in contact with a solid portion that is substantially pure SA; separating the solid portion from the liquid portion; recovering the solid portion; hydrogenating the solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product including at least one of THF, GBL or BDO; and recovering the hydrogenated product.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth, distilling the broth to form an overhead that includes water and ammonia, and a liquid bottoms that includes MAS, at least some DAS, and at least about 20 wt % water, cooling and/or evaporating the bottoms, and optionally adding an antisolvent to the bottoms, to attain a temperature and composition sufficient to cause the bottoms to separate into a DAS-containing liquid portion and a MAS-containing solid portion that is substantially free of DAS, separating the solid portion from the liquid portion, recovering the solid portion, hydrogenating the second solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product comprising at least one of THF, GBL or BDO, and recovering the hydrogenated product.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth, distilling the broth to form an overhead that includes water and ammonia, and a liquid bottoms that includes MAS, at least some DAS, and at least about 20 wt % water, cooling and/or evaporating the bottoms, and optionally adding an antisolvent to the bottoms, to attain a temperature and composition sufficient to cause the bottoms to separate into a DAS-containing liquid portion and a MAS-containing solid portion that is substantially free of DAS, separating the solid portion from the liquid portion, recovering the solid portion, hydrogenating the second solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product comprising at least one of THF, GBL or BDO, and recovering the hydrogenated product.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth, distilling the broth to form an overhead that includes water and ammonia, and a liquid bottoms that includes MAS, at least some DAS, and at least about 20 wt % water, cooling and/or evaporating the bottoms, and optionally adding an antisolvent to the bottoms, to attain a temperature and composition sufficient to cause the bottoms to separate into a DAS-containing liquid portion and a MAS-containing solid portion that is substantially free of DAS, separating the solid portion from the liquid portion, recovering the solid portion, hydrogenating the second solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product comprising at least one of THF, GBL or BDO, and recovering the hydrogenated product.

Abstract: A manifold and distribution manifold assembly is described for use in dividing the flow of an air-entrained material from a primary distribution line into a plurality of secondary distribution lines. The manifold is formed of a single molded piece thereby reducing the overall tooling cost.

Abstract: A lid for a distribution manifold is described where the manifold has an inlet opening defining an axis, access opening opposite the inlet and a plurality of radially extending outlet ports. The lid for the access opening includes a mounting member adapted to couple the lid to the manifold to close the access opening, a cone coupled to the mounting member and extending axially toward the inlet opening of the manifold when the lid is coupled to the manifold, and a single piece retainer adapted to secure the cone to the mounting member without additional fasteners.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth; distilling the broth under super atmospheric pressure at a temperature of >100° C. to about 300° C. to form an overhead that includes water and ammonia, and a liquid bottoms that includes SA, and at least about 20 wt % water; cooling the bottoms to a temperature sufficient to cause the bottoms to separate into a liquid portion in contact with a solid portion that is substantially pure SA; separating the solid portion from the liquid portion; recovering the solid portion; hydrogenating the solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product including at least one of THF, GBL or BDO; and recovering the hydrogenated product.

Abstract: A process for making a hydrogenated product includes providing a clarified DAS-containing fermentation broth; distilling the broth under super atmospheric pressure at a temperature of >100° C. to about 300° C. to form an overhead that includes water and ammonia, and a liquid bottoms that includes SA, and at least about 20 wt % water; cooling the bottoms to a temperature sufficient to cause the bottoms to separate into a liquid portion in contact with a solid portion that is substantially pure SA; separating the solid portion from the liquid portion; recovering the solid portion; hydrogenating the solid portion in the presence of at least one hydrogenation catalyst to produce the hydrogenated product including at least one of THF, GBL or BDO; and recovering the hydrogenated product.