Abstract: A chemical additive for reclaiming oil from a fluid product stream is described. In embodiments, chemical additive compositions comprise a propylene glycol ester, a hydrophobic silica, a polyglycol ester or a polyglycerol oleate ester, a polyethoxylate sorbitan or sorbitan ester and a block copolymer or ethylene oxide-propylene oxide polymer. Less chemical additive is needed for improved oil extraction and concentration and a shorter incubation time is required, which reduces cycle time and energy consumption.

Abstract: A chemical additive for reclaiming oil from a fluid product stream is described. In embodiments, chemical additive compositions comprise a propylene glycol ester, a hydrophobic silica, a polyglycol ester or a polyglycerol oleate ester, a polyethoxylate sorbitan or sorbitan ester and a block copolymer or ethylene oxide-propylene oxide polymer. Less chemical additive is needed for improved oil extraction and concentration and a shorter incubation time is required, which reduces cycle time and energy consumption.

Abstract: Processing methods may be performed to remove unwanted materials from a substrate, such as an oxide footing. The methods may include forming an inert plasma within a processing region of a processing chamber. Effluents of the inert plasma may be utilized to modify a surface of an exposed material on a semiconductor substrate within the processing region of the semiconductor chamber. A remote plasma may be formed from a fluorine-containing precursor to produce plasma effluents. The methods may include flowing the plasma effluents to the processing region of the semiconductor processing chamber. The methods may also include removing the modified surface of the exposed material from the semiconductor substrate.

Abstract: A plurality of spectra reflected from one or more substrates at a plurality of different positions on the one or more substrates are represented in the form of a first matrix, and the first matrix is decomposed into products of at least two component matrixes of a first set of component matrixes. The dimensions of each of the at least two component matrixes is reduced to produce a second set of component matrixes containing the at least two matrixes with reduced dimensions.

Abstract: A chemical additive for reclaiming oil from a fluid product stream is described. In embodiments, chemical additive compositions comprise a propylene glycol ester, a hydrophobic silica, a polyglycol ester or a polyglycerol oleate ester, a polyethoxylate sorbitan or sorbitan ester and a block copolymer or ethylene oxide-propylene oxide polymer. Less chemical additive is needed for improved oil extraction and concentration and a shorter incubation time is required, which reduces cycle time and energy consumption.

Abstract: Processing methods may be performed to form recesses in a semiconductor substrate. The methods may include oxidizing an exposed silicon surface on a semiconductor substrate within a processing region of a semiconductor processing chamber. The methods may include forming an inert plasma within the processing region of the processing chamber. Effluents of the inert plasma may be utilized to modify the oxidized silicon. A remote plasma may be formed from a fluorine-containing precursor to produce plasma effluents. The methods may include flowing the plasma effluents to the processing region of the semiconductor processing chamber. The methods may also include removing the modified oxidized silicon from the semiconductor substrate.

Abstract: An apparatus and method are provided for controlling the intensity and distribution of a plasma discharge in a plasma chamber. In one embodiment, a shaped electrode is embedded in a substrate support to provide an electric field with radial and axial components inside the chamber. In another embodiment, the face plate electrode of the showerhead assembly is divided into zones by isolators, enabling different voltages to be applied to the different zones. Additionally, one or more electrodes may be embedded in the chamber side walls.

Abstract: A method for determining overlay between layers of a multilayer structure may include obtaining a given image representing the multilayer structure, obtaining expected images for layers of the multilayer structure, providing a combined expected image of the multilayer structure as a combination of the expected images of said layers, performing registration of the given image against the combined expected image, and providing segmentation of the given image, thereby producing a segmented image, and maps of the layers of said multilayered structure. The method may further include determining overlay between any two selected layers of the multilayer structure by processing the maps of the two selected layers together with the expected images of said two selected layers.

Abstract: A plasma processing apparatus and method to control a temperature of a chamber component therein are described. A process chamber may include a temperature controlled chamber component and at least one remote heat transfer fluid loop comprising a first heat exchanger having a primary side in fluid communication with a heat sink or heat source, and a local heat transfer fluid loop placing the chamber component in fluid communication with a secondary side of the first heat exchanger. The local loop may be of significantly smaller fluid volume than the remote loop(s) and circulated to provide thermal load of uniform temperature. Temperature control of heat transfer fluid in the local loop and temperature control of the chamber component may be implemented with a cascaded control algorithm. The plasma processing apparatus further includes an AC heated electrostatic chuck (ESC) assembly.

Abstract: A method and system for linking sensor data to metrology data and metrology data to sensor data is described herein. In one embodiment, a user selection of metrology data for a product is received, related process tool fault detection summary for the selected metrology data for the product is presented, a user selection of a process tool from the process tool fault detection summary is received, and related fault detection details for the selected process tool are presented.

Abstract: Methods for forming fin structure with desired materials formed on different locations of the fin structure using a selective deposition process for three dimensional (3D) stacking of fin field effect transistor (FinFET) for semiconductor chips are provided. In one embodiment, a method of forming a structure with desired materials on a substrate includes forming a patterned self-assembled monolayer on a circumference of a structure formed on a substrate, wherein the patterned self-assembled monolayer includes a treated layer formed among a self-assembled monolayer, and performing an atomic layer deposition process to form a material layer predominantly on the self-assembled monolayer from the patterned self-assembled monolayer.

Abstract: Embodiments of the invention generally relate to solid state battery structures, such as Li-ion batteries, methods of fabrication and tools for fabricating the batteries. One or more electrodes and the separator may each be cast using a green tape approach wherein a mixture of active material, conductive additive, polymer binder and/or solid electrolyte are molded or extruded in a roll to roll or segmented sheet/disk process to make green tape, green disks or green sheets. A method of fabricating a solid state battery may include: preparing and/or providing a green sheet of positive electrode material; preparing and/or providing a green sheet of separator material; laminating together the green sheet of positive electrode material and the green sheet of separator material to form a laminated green stack; and sintering the laminated green stack to form a sintered stack comprising a positive electrode and a separator.

Abstract: A substrate for use in fabrication of an integrated circuit has a layer with a plurality of conductive interconnects. The substrate includes a semiconductor body, a dielectric layer disposed over the semiconductor body, a plurality of conductive lines of a conductive material disposed in first trenches in the dielectric layer to provide the conductive interconnects, and a closed conductive loop structure of the conductive material disposed in second trenches in the dielectric layer. The closed conductive loop is not electrically connected to any of the conductive lines.

Abstract: Embodiments of the present invention provide apparatus and methods for reducing non-uniformity and/or skews during substrate processing. One embodiment of the present invention provides a flow equalizer assembly for disposing between a vacuum port and a processing volume in a processing chamber. The flow equalizing assembly includes a first plate having at least one first opening, and a second plate having two or more second openings. The first and second plates define a flow redistributing volume therebetween, and the at least one first opening and the two or more second openings are staggered.

Abstract: The present disclosure provides methods and an apparatus for controlling and modifying line width roughness (LWR) of a photoresist layer with enhanced electron spinning control. In one embodiment, an apparatus for controlling a line width roughness of a photoresist layer disposed on a substrate includes a processing chamber having a chamber body having a top wall, side wall and a bottom wall defining an interior processing region, a support pedestal disposed in the interior processing region of the processing chamber, and a plasma generator source disposed in the processing chamber operable to provide predominantly an electron beam source to the interior processing region.

Abstract: An electronic device manufacturing system is disclosed. The system includes a processing tool having one or more processing chambers each adapted to perform an electronic device manufacturing process on one or more substrates; a substrate carrier adapted to couple to the system and carry one or more substrates; and a component adapted to create a sealed environment relative to at least a portion of the substrate carrier and to substantially equalize the sealed environment with an environment within the substrate carrier. Methods of the invention are described as are numerous other aspects.

Abstract: A process for generating a compact alumina passivation layer on an aluminum component includes rinsing the component in deionized water for at least one minute, drying it for at least one minute, and exposing it to concentrated nitric acid, at a temperature below 10° C., for one to 30 minutes. The process also includes rinsing the component in deionized water for at least one minute, drying it for at least one minute, and exposing it to NH4OH for one second to one minute. The process further includes rinsing the component in deionized water for at least one minute and drying it for at least one minute. A component for use in a plasma processing system includes an aluminum component coated with an AlxOy film having a thickness of 4 to 8 nm and a surface roughness less than 0.05 ?m greater than a surface roughness of the component without the AlxOy film.

Abstract: Embodiments described herein generally relate to apparatus for heating substrates. The apparatus generally include a process chamber having a substrate support therein. A plurality of lamps is positioned to provide radiant energy through an optically transparent dome to a substrate positioned on the substrate support. A light focusing assembly is positioned within the chamber to influence heating and temperature distribution on the substrate and to facilitate formation of a film on a substrate having uniform properties, such as density. The light focusing assembly can include one or more reflectors, light pipes, or refractive lenses.

Abstract: A gas distribution plate for a plasma reactor has a dielectric front plate and a dielectric back plate bonded together, with gas injection orifices extending through the front plate and gas supply channels in the surface of front plate facing the back plate. The back plate is joined to a heat reflective plate, or the back plate itself is formed of a heat reflective material, such as Beryllium Oxide.

Abstract: A deposited amorphous carbon film includes at least 95% carbon. A percentage of sp3 carbon-carbon bonds present in the amorphous carbon film exceeds 30%, and a hydrogen content of the amorphous carbon film is less than 5%. A process of depositing amorphous carbon on a workpiece includes positioning the workpiece within a process chamber and positioning a magnetron assembly adjacent to the process chamber. The magnetron assembly projects a magnetic field into the process chamber. The method further includes providing a carbon target such that the magnetic field extends through the carbon target toward the workpiece. The method further includes providing a source gas to the process chamber, and providing pulses of DC power to a plasma formed from the source gas within the process chamber. The pulses of DC power are supplied in pulses of 40 microseconds or less, that repeat at a frequency of at least 4 kHz.