Abstract: The invention pertains to a system, and related methods, for the percutaneous transluminal delivery and retrieval of a prosthetic occluder through a front-end loader. The prosthetic occluder may be, for example, an intracardiac occluder for a patent foramen ovale. The system includes, in one embodiment, a front-end loader having a beveled distal end. In another embodiment, the system includes a front-end loader having a chamfered rim at the beveled distal end.

Abstract: The invention pertains to a system, and related methods, for the percutaneous transluminal delivery and retrieval of a prosthetic occluder through a front-end loader. The prosthetic occluder may be, for example, an intracardiac occluder for a patent foramen ovale. The system includes, in one embodiment, a front-end loader having a beveled distal end. In another embodiment, the system includes a front-end loader having a chamfered rim at the beveled distal end.

Abstract: A method of making metal articles as well as sputtering targets is described, which involves deforming an ingot to preferred dimensions. In addition, products made by the process of the present invention are further described.

Abstract: A method of making metal articles as well as sputtering targets is described, which involves deforming an ingot to preferred dimensions. In addition, products made by the process of the present invention are further described.

Abstract: A method for removing impurities (e.g., atomic sulfur) from a reticle for use in photolithography is provided. In one embodiment, a reticle (or photomask) comprising a plate, a first layer over the plate, and a photoresist layer over the first layer is provided. The photoresist layer is removed with a first chemistry comprising a sulfur-containing compound. At least a portion of the first layer is removed with a second chemistry comprising a sulfur-containing etchant, thereby exposing portions of the plate. Removing the photoresist layer and/or at least a portion of the first layer leaves sulfur on at least portions of the reticle. In a cleaning step, the reticle is contacted with one or more excited species of oxygen to remove residual sulfur and other contaminants, such as carbon, sulfur and oxygen-containing species. Methods of embodiments can be used to clean, e.g., binary photomasks, attenuated phase shift masks (APSMs) and high transmission attenuated photomasks.

Abstract: An apparatus for depositing materials onto a micro-device workpiece includes a gas source system configured to provide a first precursor, a second precursor, and a purge gas. The apparatus can also include a valve assembly coupled to the gas source system. The valve assembly is configured to control a flow of the first precursor, a flow the second precursor, and a flow of the purge gas. Another component of the apparatus is a reaction chamber including an inlet coupled to the valve assembly, a workpiece holder in the reaction chamber, and an outlet downstream from the workpiece holder. The apparatus also includes a monitoring system and a controller. The monitoring system comprises a radiation source that directs a selected radiation through the reaction chamber and a detector that senses a parameter of the radiation directed through the reaction chamber. The controller is operatively coupled to the monitoring system and the valve assembly.

Abstract: A chemical vapor deposition apparatus includes a deposition chamber defined at least in part by at least one of a chamber sidewall and a chamber base wall. A substrate holder is received within the chamber. At least one process chemical inlet to the deposition chamber is included. At least one of the chamber sidewall and chamber base wall includes a chamber surface having a plurality of purge gas inlets to the chamber therein. The purge gas inlets are separate from the at least one process chemical inlet. A purge gas inlet passageway is provided in fluid communication with the purge gas inlets. Further implementations, including deposition method implementations, are contemplated.

Abstract: Reactors having gas distributors for depositing materials onto micro-device workpieces, systems that include such reactors, and methods for depositing materials onto micro-device workpieces. In one embodiment, a reactor for depositing materials onto a micro-device workpiece includes a reaction chamber, a passageway, and a door assembly. The reaction chamber includes a gas distributor configured to provide a flow of gas(es) to a micro-device workpiece on a workpiece holder. The passageway, which has a first end open to the reaction chamber and a second end apart from the reaction chamber, is configured to provide ingression to and egression from the chamber for processing the micro-device workpiece. The door assembly is configured to open and sealably close a door at the second end of the passageway. A gas conditioning system positioned in the door is configured to maintain a desired concentration and phase of gas constituents in the passageway.

Abstract: The invention includes a deposition apparatus having a reaction chamber, and a microwave source external to the chamber. The microwave source is configured to direct microwave radiation toward the chamber. The chamber includes a window through which microwave radiation from the microwave source can pass into the chamber. The invention also includes deposition methods (such as CVD or ALD methods) in which microwave radiation is utilized to activate at least one component within a reaction chamber during deposition of a material over a substrate within the reaction chamber.

Abstract: Reactors for vapor deposition of materials onto a microelectronic workpiece, systems that include such reactors, and methods for depositing materials onto microelectronic workpieces. In one embodiment, a reactor for vapor deposition of a material comprises a reaction chamber and a gas distributor. The reaction chamber can include an inlet and an outlet. The gas distributor is positioned in the reaction chamber. The gas distributor has a compartment coupled to the inlet to receive a gas flow and a distributor plate including a first surface facing the compartment, a second surface facing the reaction chamber, and a plurality of passageways. The passageways extend through the distributor plate from the first surface to the second surface. Additionally, at least one of the passageways has at least a partially occluded flow path through the plate.

Abstract: A chemical vapor deposition apparatus includes a deposition chamber defined at least in part by chamber walls, a substrate holder inside the chamber, and at least one process chemical inlet to the chamber. At least one purge inlet to the chamber is positioned elevationally above the substrate holder and outside a lateral periphery of the substrate holder. The purge inlet is configured to inject at least one purge material into the chamber and past the substrate holder. The purge inlet can be positioned and configured to inject an annular purge material curtain concentric to the substrate holder. A chemical vapor deposition method includes injecting at least one purge material into a deposition chamber and forming a purge curtain from the injected purge material. The purge curtain can extend downward from elevationally above a substrate holder and outside a lateral periphery of the substrate holder. The purge curtain can flow past the substrate holder.

Abstract: A method for removing impurities (e.g., atomic sulfur) from a reticle for use in photolithography is provided. In one embodiment, a reticle (or photomask) comprising a plate, a first layer over the plate, and a photoresist layer over the first layer is provided. The photoresist layer is removed with a first chemistry comprising a sulfur-containing compound. At least a portion of the first layer is removed with a second chemistry comprising a sulfur-containing etchant, thereby exposing portions of the plate. Removing the photoresist layer and/or at least a portion of the first layer leaves sulfur on at least portions of the reticle. In a cleaning step, the reticle is contacted with one or more excited species of oxygen to remove residual sulfur and other contaminants, such as carbon, sulfur and oxygen-containing species. Methods of embodiments can be used to clean, e.g., binary photomasks, attenuated phase shift masks (APSMs) and high transmission attenuated photomasks.

Abstract: Methods, apparatuses, and systems for controlling mass flow rates and pressures in passageways coupled to reaction chambers are disclosed herein. In one embodiment, a method includes controlling a mass flow rate in a passageway in response to a first condition by modulating a valve of a mass flow and pressure control unit, and controlling a pressure in the passageway in response to a second condition different than the first condition by modulating the valve of the mass flow and pressure control unit. In another embodiment, an apparatus includes a mass flow measurement device, a pressure sensor, a modulating valve in the passageway, and a controller operably coupled to the mass flow measurement device, the pressure sensor, and the modulating valve. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: A method of forming a film on a substrate includes activating a gas precursor to form a material on the substrate by irradiating the gas precursor with electromagnetic energy at a frequency tuned to an absorption frequency of the gas precursor.

Abstract: A chemical vapor deposition apparatus includes a subatmospheric substrate transfer chamber. A subatmospheric deposition chamber is defined at least in part by a chamber sidewall. A passageway in the chamber sidewall extends from the transfer chamber to the deposition chamber. Semiconductor substrates pass into and out of the deposition chamber through the passageway for deposition processing. A mechanical gate is included within at least one of the deposition chamber and the sidewall passageway, and is configured to open and close at least a portion of the passageway to the chamber. A chamber liner apparatus of a chemical vapor deposition apparatus forms a deposition subchamber within the chamber. At least a portion of the chamber liner apparatus is selectively movable to fully expose and to fully cover the passageway to the chamber.

Abstract: A method of making metal articles as well as sputtering targets is described, which involves deforming an ingot to preferred dimensions. In addition, products made by the process of the present invention are further described.

Abstract: A method includes removing at least a piece of a deposition chamber liner from a deposition chamber by passing it through a passageway to the deposition chamber through which semiconductor substrates pass into and out of the chamber for deposition processing. A replacement for the removed deposition chamber liner piece is provided into the chamber by passing the replacement through said passageway. A liner apparatus includes a plurality of pieces which when assembled within a selected semiconductor substrate deposition processor chamber are configured to restrict at least a majority portion of all internal wall surfaces which define said semiconductor substrate deposition processor chamber from exposure to deposition material within the chamber. At least some of the pieces are sized for passing completely through a substrate passageway to the chamber through which semiconductor substrates pass into and out of the chamber for deposition processing.

Abstract: Methods of chemical vapor deposition include providing a deposition chamber defined at least in part by at least one of a chamber sidewall and a chamber base wall. At least one process chemical inlet to the deposition chamber is included. A substrate is positioned within the chamber and a process gas is provided over the substrate effective to deposit material onto the substrate. While providing the process gas, a purge gas is emitted into the chamber from a plurality of purge gas inlets comprised by at least one chamber wall surface. The purge gas inlets are separate from the at least one process chemical inlet and the emitting forms an inert gas curtain over the chamber wall surface.

Abstract: A semiconductor substrate processor includes a substrate transfer chamber and a plurality of substrate processing chambers connected therewith. An interfacial structure is received between at least one of the processing chambers and the transfer chamber. The interfacial structure includes a substantially non-metallic, thermally insulative mass of material interposed between the one processing chamber and the transfer chamber. The mass is of sufficient volume to effectively reduce heat transfer from the processing chamber to the transfer chamber than would otherwise occur in the absence of said mass of material. An interfacial structure includes a body having a substrate passageway extending therethrough. The passageway includes walls at least a portion of which are substantially metallic. The body includes material peripheral of the walls which is substantially non-metallic and thermally insulative. The substantially non-metallic material has mounting openings extending at least partially therein.

Abstract: A chemically sensitive warning apparatus capable of changing colors upon contact with a chemical is disclosed. The apparatus preferably comprises an elongated tape having opposed, first and second major surfaces and warning indicia visible to an individual viewing the first surface to provide visual indication of possible danger or hazardous condition. Mounted to the tape is at least one chemical indicator that is responsive to the presence of at least one chemical by changing colors so as to provide a visual indication of the exposure of the indicator to the chemical. The tape may also include at least one color reference indicia to facilitate interpretation of the color of the chemical indicator when the chemical indicator changes color upon exposure to the chemical.