Abstract: A wafer cleaning apparatus includes a polishing unit used in chemical mechanical polishing (CMP) of a wafer and a cleaning dispensing unit arranged to direct cleaning fluids toward a far edge of the wafer after the CMP of the wafer. A wafer cleaning method includes CMP of a wafer by a polishing unit and directing cleaning fluids toward a far edge of the wafer after the CMP of the wafer by a cleaning dispensing unit. Another method can include CMP, applying deionized water, and applying pH adjuster having a pH range from about 2 to about 13.

Abstract: A polishing device for optical elements includes: a tool shank (1), and a polishing disc base; wherein the tool shank (1) is connected to the polishing disc base and is mounted on a tool shaft of a numerical-controlled processing device; wherein a polishing film (3) is stuck on the polishing disc base; the polishing disc base is a profiling polishing disc base (7), a cylinder polishing disc base (2), a profiling polishing disc base (12) or a spherical polishing disc base (8); wherein the tool shank (1) is independent and universal, thereby reducing the processing cost of the polishing device. A polishing method for optical elements is based on the shapes mentioned above of the polishing disc base, including steps of: fixing a polishing disc connecting rod (11); sticking a polishing film (3); trimming the polishing film (3); and polishing an unprocessed work piece (6).

Abstract: A substrate bonding apparatus includes a lower chuck that receives a lower substrate and an upper chuck disposed above the lower chuck. An upper substrate is fixed to the upper chuck. The upper chuck and the lower chuck bond the upper substrate to the lower substrate. The upper chuck has an upper convex surface toward the lower chuck. The upper convex surface includes a plurality of first ridges and a plurality of first valleys disposed alternately along an azimuthal direction.

Abstract: A vacuum chuck includes an adsorption plate including porous materials, a housing including an accommodation part, a plurality of adsorption grooves, and a vacuum opening formed in the accommodation part. The adsorption plate is disposed in the accommodation part, and the plurality of adsorption grooves each have an arc shape and is formed in a surface of the accommodation part. The vacuum chuck further includes a vacuum line configured to supply vacuum pressure to the vacuum opening.

Abstract: A method for fabricating vacuum tooling is disclosed using porous granular media. A sheet of steel webbing is affixed to a frame. A plurality of layers of fiberglass is affixed to the webbing. A vacuum port is installed through the webbing and plurality of layers of fiberglass. A granular media is mixed with epoxy to form a granular mixture. The granular mixture is layered over the plurality of layers of fiberglass to form a flat surface and machined for uniformity before sealing.

Abstract: A method includes: vacuuming at least one area among a plurality of areas formed concentrically between a top face of the elastic film and the top ring body under a state where a bottom face of the substrate is supported by a support member and a top face of the substrate contacts a bottom face of the elastic film; measuring a flow volume of gas in an area located outside one or more areas to be vacuumed; determining whether the substrate is adsorbed to the top ring based on the flow volume of the gas; and after it is determined that the substrate is adsorbed to the top ring, separating the elastic film to which the substrate is adsorbed from the support member.

Abstract: A chuck table for holding a plate-shaped workpiece under suction includes a suction plate made of porous ceramics and having a plurality of open pores, and a frame covering a side surface and a reverse side, except an attractive suction surface, of the suction plate and having a plurality of suction grooves defined in an upper surface thereof and a fluid communication passage defined therein that holds the suction grooves in fluid communication with a suction source, the frame supporting the suction plate thereon. The suction plate has a porosity in the range from 60% to 70% by volume, and the open pores have diameters in the range from 10 ?m to 25 ?m.

Abstract: A transport system is provided. The transport system includes a stocker configured to store an assigned wafer carrier and having a gate port. The transport system also includes a semiconductor apparatus configured to transmit a request signal comprising a processed time according to a processing wafer carrier loaded on the semiconductor apparatus. The transport system further includes a vehicle configured to transport the assigned wafer carrier from the gate port to the semiconductor apparatus and a control system configured to control the vehicle. When the control system receives the request signal, the control system controls the stocker to transport the assigned wafer carrier inside of the stocker to the gate port at a start time, which is earlier than the processed time, and the control system controls the vehicle to transport the assigned wafer carrier from the gate port to the semiconductor apparatus.

Abstract: A grinding apparatus includes a holding unit including a holding table having a holder for holding a workpiece and a grinding water suction part for drawing in grinding water outside of the holder, a rotational shaft having an end fixed centrally to a bottom surface of the holding table, a tubular rotary joint surrounding the rotational shaft, and a motor rotating the rotational shaft about its own axis. The rotational shaft has a first suction channel held in fluid communication with the holder of the holding table and a second suction channel held in fluid communication with the grinding water suction part. The rotary joint has a communication channel by which the first suction channel and the second suction channel are held in fluid communication with at least a suction source.

Abstract: A chuck table is provided and a substrate processing system including the same. The chuck table includes a base disk having a first vacuum hole, and a chuck disk disposed on the first vacuum hole. The chuck disk includes a plurality of first sectors and a first connection member connecting the first sectors to each other.

Abstract: A polishing apparatus polishes a periphery of a substrate by bringing a polishing tool into sliding contact with the substrate. The polishing apparatus includes a substrate-holding mechanism configured to hold a substrate and rotate the substrate, a polishing mechanism configured to press a polishing tool against a periphery of the substrate so as to polish the periphery, and a periphery-supporting mechanism configured to support the periphery of the substrate by a fluid. The periphery-supporting mechanism is configured to support a surface of the substrate from an opposite side or the same side of the periphery of the substrate.

Abstract: A method for operating a polishing head is provided. The method includes keeping a stator of at least one electromagnetism actuated pressure sector stationary with respect to a carrier head, and electromagnetically and linearly moving an active cell of the electromagnetism actuated pressure sector with the stator to linearly move the active cell with respect to the carrier head.

Abstract: A processing apparatus includes a rotary table that causes a workpiece to rotate around a rotary axis, a roller-shaped member that rotates on an axis orthogonal to the rotary axis of the rotary table, a vertical driving section that is driven in a direction of the rotary axis of the rotary table so as to bring the roller-shaped member and the workpiece into contact with each other, an ultraviolet ray irradiation source that irradiates a portion between the roller-shaped member and the workpiece with an ultraviolet ray, a polishing material that is supplied to the portion between the roller-shaped member and the workpiece, and a light scattering medium that is supplied to the portion between the roller-shaped member and the workpiece and scatters an ultraviolet ray from the ultraviolet ray irradiation source.

Abstract: A polishing apparatus polishes a periphery of a substrate by bringing a polishing tool into sliding contact with the substrate. The polishing apparatus includes a substrate-holding mechanism configured to hold a substrate and rotate the substrate, a polishing mechanism configured to press a polishing tool against a periphery of the substrate so as to polish the periphery, and a periphery-supporting mechanism configured to support the periphery of the substrate by a fluid. The periphery-supporting mechanism is configured to support a surface of the substrate from an opposite side or the same side of the periphery of the substrate.

Abstract: A fluidic media detection system for detecting a presence of fluidic media includes a first housing portion adapted to be carried by a user; a second housing portion configured to be selectively operatively engaged with and disengaged from the first housing portion, the second housing portion for supporting a reservoir having an interior volume for containing fluidic media; a fluid conduit supported by one of the first housing portion and the second housing portion for providing fluid communication between the reservoir and the user when the first housing portion and the second housing portion are operatively engaged; and at least one interactive element, positioned near a portion of the fluid conduit, that interacts with the fluidic media when the fluidic media is present in the fluid conduit.

Abstract: The present invention provides a polishing head including: an annular rigid ring; an elastic film bonded to the rigid ring; and an upward and downward movable mid-plate, the mid-plate defining a first sealed space together with the rigid ring and the elastic film; an incompressible fluid enclosed in a sealed space; and a mid-plate positioning device for adjusting vertical position of the mid-plate, to hold a back surface of a workpiece on a lower surface of the elastic film and polish a front surface by bringing the front surface into contact with a polishing pad attached to a turn table, wherein the mid-plate can adjust a shape of the lower surface of the elastic film by adjusting the vertical position of the mid-plate. The polishing head polishes a workpiece without generating surface defects on the workpiece surface and easy detachment of the workpiece from a polishing pad after polishing.

Abstract: A retaining ring includes an annular lower portion and an annular upper portion. The annular lower portion has a main body with a bottom surface for contacting a polishing pad during polishing, an inner rim projecting upward from the main body, an outer rim projecting upward from the main body and separated from the inner rim by a gap, and a plurality of azimuthally separated interlock features positioned between the inner rim and the outer rim, each interlock feature projecting upwardly from the main body. The annular upper portion has a top surface and a bottom surface and a plurality of azimuthally separated recesses in the bottom surface, the recesses defining thin portions of the upper portion, the plurality of interlock features fitting into the plurality of recesses. The lower portion is a plastic and the upper portion is a material that is more rigid than the plastic.

Abstract: Flat-surfaced workpieces such as semiconductor wafers or sapphire disks are attached to a rotatable floating or rigid workpiece holder carrier that is supported by a pressurized-air flexible elastomer disk sealed air-chamber device and is rotationally driven by a flexible arm or a lug-pin device. The rotating wafer carrier rotor is horizontally restrained by a set of idlers that are attached to a stationary housing to provide rigid support against abrading forces. The abrading system can be operated at the very high abrading speeds used in high speed flat lapping with raised-island abrasive disks. A wide range of abrading pressures are applied uniformly across the surface of the workpiece. Vacuum can also be applied to the elastomer chamber to quickly move the wafer away from the abrading surface. Internal constraints limit the axial, lateral and circumferential motion of the workholder. Wafers can be quickly attached to the workpiece carrier with vacuum.

Abstract: A system includes a chuck with a retaining ring on a first surface thereof. The first surface and the retaining ring are both circular, the retaining ring having a first inner circumference. The system also includes a platen with a second surface, and the second surface faces the first surface and is operable to move with the first surface. The system further includes an air zone circumscribed by the first inner circumference that provides an effective inner circumference different from the first inner circumference.

Abstract: A polishing apparatus includes a platen to hold a polishing pad having a plurality of optical apertures, a carrier head to hold a substrate against the polishing pad, a motor to generate relative motion between the carrier head and the platen, and an optical monitoring system. The optical monitoring system includes at least one light source, a common detector, and an optical assembly configured to direct light from the at least one light source to each of a plurality of separated positions in the platen, to direct light from each position of the plurality of separated positions to the substrate as the substrate passes over said each position, to receive reflected light from the substrate as the substrate passes over said each position, and to direct the reflected light from each of the plurality of separated positions to the common detector.

Abstract: A method of transporting a semiconductor wafer having a ring-shaped stiffening portion can include the steps of pressing the semiconductor wafer from the back surface side to the front surface side thereof on a place different from a place at which the semiconductor wafer is to be held, the step of pressing the semiconductor wafer being conducted before holding the semiconductor wafer having the ring-shaped stiffening portion. The method can include releasing the attachment by suction of the front surface of the semiconductor wafer by supplying a positive pressure onto the chuck table, releasing pressing the semiconductor wafer from the back surface side to the front surface side thereof on the place different from the place at which the semiconductor wafer is to be held and picking up the semiconductor wafer having the ring-shaped stiffening portion from the chuck table while holding the semiconductor wafer.

Abstract: An apparatus for processing a substrate is disclosed. The apparatus includes a polishing section configured to polish a substrate, a transfer mechanism configured to transfer the substrate, and a cleaning section configured to clean and dry the polished substrate. The cleaning section has plural cleaning lines for cleaning plural substrates. The plural cleaning lines have plural cleaning modules and plural transfer robots for transferring the substrates.

Abstract: A chemical mechanical polishing apparatus includes a platen having a first region configured to support a wafer, and a second region disposed outside the first region. The chemical mechanical polishing apparatus further includes a polishing pad disposed on the platen, a pad head to which the polishing pad is attached, a slurry supply configured to supply a slurry onto the wafer, and an injection port disposing on the second region of the platen. The injection port is configured to inject a predetermined gas to an edge of a bottom surface of the wafer and toward the outside of the wafer.

Abstract: The present invention comprises of a process for lapping a high-throughput of ultra-flat wafers by utilizing a lapping apparatus containing a rotary flat, grooved polishing platen, at least two rotating pressurized heads each having a polishing wafer carrier that is adapted to receive a plurality of mounted wafers, and a plurality of concentric conditioning rings surrounding each pressurized head. The rotating pressurized heads are counterbalanced throughout the inventive process, and the lapping platen is continuously conditioned by simultaneously rotating the concentric conditioning rings over the lapping platen. This process allows continuous and controllable planarization thus allowing for a high throughput of wafers, while at the same time it prevents distortions in the lapping platen which reduces maintenance by providing continuous conditioning of the lapping platen.

Abstract: A device for finish-machining of the optically effective surfaces of, in particular, spectacle lenses has a spindle shaft, which has a tool mount section and which is mounted in a spindle housing to be rotatable about a workpiece rotational axis (A). An electric rotary drive has a rotor and a stator by which the spindle shaft operatively connected with the rotor is drivable to rotate about the tool rotational axis. An adjusting device axially displaces the tool mount section with respect to the spindle housing in the direction of the tool rotational axis (linear movement Z). The rotor and the stator are arranged coaxially with the spindle shaft, wherein at least the rotor together with the spindle shaft is axially displaceable with respect to the spindle housing in the direction of the tool rotational axis by the adjusting device.

Abstract: An apparatus and a method for forming or polishing a concave or convex radius surface on a work-piece is described herein. The apparatus includes a carrier that is configured to support a work-piece. A substantially hollow rotatable tool, which includes a circumferential surface for either forming or polishing the radius surface, is positioned adjacent the carrier. An axis of rotation of the tool is oriented at an oblique angle with respect to a longitudinal axis of the work-piece and a longitudinal axis of the carrier. Alternatively, the longitudinal axis of the work-piece may be laterally offset from the longitudinal axis of the carrier. The apparatus further includes provisions for rotating the hollow rotatable tool for forming or polishing a radius surface on the surface of the work-piece.

Abstract: A polishing head for holding a workpiece when a surface of the workpiece is polished and a polishing apparatus provided with the polishing head, and more particularly a polishing head for holding the workpiece on a rubber film and a polishing apparatus provided with the polishing head. The polishing head and the polishing apparatus provided with the polishing head that can adjust the polishing profile on the basis of the shape of the workpiece before polishing and can stably obtain good flatness.

Abstract: A polishing apparatus includes a platen to hold a polishing pad having a plurality of optical apertures, a carrier head to hold a substrate against the polishing pad, a motor to generate relative motion between the carrier head and the platen, and an optical monitoring system. The optical monitoring system includes at least one light source, a common detector, and an optical assembly configured to direct light from the at least one light source to each of a plurality of separated positions in the platen, to direct light from each position of the plurality of separated positions to the substrate as the substrate passes over said each position, to receive reflected light from the substrate as the substrate passes over said each position, and to direct the reflected light from each of the plurality of separated positions to the common detector.

Abstract: A substrate holder is a mechanism for holding a substrate, to be polished, by vacuum suction. The substrate holder includes a substrate-holding stage having a suction surface for the substrate, and a fluid passage selectively coupled to a vacuum source and a fluid supply source. The suction surface has a plurality of closed sections surrounded by convexities, and the fluid passage includes a plurality of communication passages which are in fluid communication with the plurality of closed segments respectively and independently.

Abstract: A polishing system includes a polishing pad with an aperture that extends through all layers of the polishing pad and a light transmissive film positioned on top of a light-generating or light-guiding element of an optical monitoring system.

Abstract: A polishing apparatus is used for polishing a substrate such as a semiconductor wafer to a flat mirror finish. The polishing apparatus includes a polishing table (100) having a polishing surface (101a), a top ring body (2) configured to hold and press a substrate against the polishing surface (101a), and a retainer ring (3) provided at an outer peripheral portion of the top ring body (2) and configured to press the polishing surface (101a). A fulcrum for receiving a lateral force applied from the substrate to the retainer ring (3) during polishing of the substrate is located above a central portion of the substrate.

Abstract: A polishing method can bring a polishing surface to the optimum condition for polishing, without using a dummy wafer, before resuming polishing, thereby eliminating the cost of dummy wafer. The polishing method includes carrying out a stand-by operation during a polishing-resting time period, carrying out a preparatory process to polishing, after completion of the stand-by operation, by dressing a polishing surface while supplying a polishing liquid to the polishing surface, and starting polishing of a workpiece after completion of the preparatory process to polishing. A determination as to whether to carry out the preparatory process to polishing after completion of the stand-by operation may be made based on the total operating time of the stand-by operation or the total effective number of the stand-by operations.

Abstract: A workpiece holder for polishing includes a workpiece holder body having multiple perforated holes to hold a workpiece by vacuum suction. A holding surface of the workpiece holder body may be coated with resin. A coefficient of thermal expansion of the resin coating on the holding surface may be 1×10?5/K or less. The resin coating on the holding surface may be epoxy resin filled with silica particles.

Abstract: The invention relates to a device for applying and/or detaching a wafer to/from a carrier with a deformable membrane which can be aligned parallel to the contact surface of the wafer, with one contact side for at least partial contact-making with the contact surface, deformation means which are located backward to the contact side for deformation of the membrane which can be controlled in a defined manner and adhesion means for adhesion of the wafer to the membrane and process for detaching and/or applying a wafer to/from a carrier with a corresponding device.

Abstract: An article of manufacture, a method, and an apparatus for use in a chemical mechanical polishing system is provided. In one aspect, an article of manufacture is provided for polishing a substrate including a polishing article having a polishing surface, the polishing surface including a first polishing portion having a first polishing material of a first hardness for polishing a first portion of the substrate, and a second polishing portion having a second polishing material of a second hardness for polishing a second portion of the substrate. The article of manufacturer may be disposed on a rotatable, stationary, or linear platen for processing a substrate. In another aspect, a method is provided for processing a substrate, including providing a platen containing the polishing article disposed on the rotatable platen, delivering a polishing composition to the polishing article, and contacting a substrate on the polishing article.

Abstract: Provided are a substrate supporting unit and a single type substrate polishing apparatus using the substrate supporting unit. During a polishing process, the bottom surface of a substrate is attached to the substrate supporting unit by vacuum suction, and during a post-cleaning process, the substrate is supported by the substrate supporting unit at a position spaced apart from the substrate supporting unit for cleaning the bottom surface of the substrate. Therefore, according to the substrate supporting unit and the substrate polishing apparatus using the substrate supporting unit, in a state where the substrate is supported by the single type substrate supporting unit, a process for polishing the top surface of the substrate and a post-process for cleaning the top and bottom surfaces of the substrate can be sequentially performed.

Abstract: A method for manufacturing an optical projection reticle employs a damascene process. First feature recesses are etched into a projection reticle mask plate which is transmissive or transparent. Then feature recesses are tilled with a radiation transmissivity modifying material comprising a partially transmissive material and/or a radiation absorber for absorbing actinic radiation. Sacrificial materials may be added to the recess temporarily prior to filling the recess to provide gaps juxtaposed with the material filling the recess. Thereafter, the sacrificial materials are removed. Then the projection mask is planarized leaving feature recesses filled with transmissivity modifying material, and any gaps desired. The projection mask is planarized while retained in a fixture holding it in place during polishing with a polishing tool and a slurry.

Abstract: A polishing apparatus is used for polishing a substrate such as a semiconductor wafer to a flat mirror finish. The polishing apparatus includes a polishing table having a polishing surface, a polishing head having at least one elastic membrane configured to form a plurality of pressure chambers for being supplied with a pressurized fluid, and a controller configured to control supply of the pressurized fluid to the pressure chambers. The controller controls supply of the pressurized fluid so that the pressurized fluid is supplied first to the pressure chamber located at a central portion of the substrate when the substrate is brought into contact with the polishing surface, and then the pressurized fluid is supplied to the pressure chamber located at a radially outer side of the pressure chamber located at the central portion of the substrate.

Abstract: The present embodiment provides for methods and systems for use in processing objects such as wafers, including polishing and/or grinding wafers. Some embodiments provide systems that include a front-end module and a processing module. The front end module couples with a storage device that stores objects for processing. The front-end module can comprise a single robot, a transfer station, and a plurality of end effectors. The processing module is coupled with the front-end module such that the single robot delivers objects from the storage device to the processing module. The processing module comprising a rotating table, and a spindle with a carrier configured to retrieve the delivered object and process the object on the rotating table.

Abstract: The present invention is a polishing head in which a rubber film is formed in a boot shape in such a manner that a position where the rubber film is held by a mid plate is distantly positioned from a work holding portion; an end portion of the boot shaped rubber film is formed in O-ring shape so that the rubber film is held by the mid plate with decreasing an area of contact between the mid plate and the rubber film as much as possible. As a result, there is provided a polishing head with rubber chuck method in which an occurrence of a surface defect, such as a scratch, on a surface of the work is suppressed as much as possible and the work can be uniformly and stably polished to the outer periphery.

Abstract: Embodiments of the present invention generally relate to a substrate transferring system. One embodiment of the present invention provides a substrate holder comprising a pedestal plate, a basin wall extending from a top surface of the pedestal plate, wherein the basin wall has a substantially leveled top surface, the basin wall and the pedestal plate define a basin configured to retain a liquid therein, and a liquid port opening to the basin, wherein the liquid port is configured to flow a liquid to the basin and allow the liquid to overflow from the basin wall, and a top surface of the overflow liquid in the basin is configured to support a substrate without contacting the basin wall or the pedestal plate.

Abstract: A chuck for releasably retaining a substrate, where the chuck has a body with a substrate receiving surface disposed in an X-Y coordinate plane and adapted to receive the substrate. The body has gas pressure delivery channels and gas vacuum drawing channels, where the gas pressure delivery channels and gas vacuum drawing channels are mutually exclusive within the body. The substrate receiving surface has gas pressure delivery portions in communication with the gas pressure delivery channels, for delivering a gas pressure against the substrate while the substrate is retained by the chuck, and thereby keeping the substrate from contacting the substrate receiving surface. The substrate receiving surface also has gas vacuum drawing portions in communication with the gas vacuum drawing channels, for drawing a gas vacuum against the substrate while the substrate is retained by the chuck, and thereby retaining the substrate proximate the substrate receiving surface.

Abstract: A substrate polishing apparatus includes a substrate holding mechanism having a head for holding a substrate to be polished, and a polishing mechanism including a polishing table with a polishing pad mounted thereon. The substrate held by the head is pressed against the polishing pad on the polishing table to polish the substrate by relative movement of the substrate and the polishing pad. The substrate polishing apparatus also includes a substrate transfer mechanism for delivering the substrate to be polished to the head and receiving the polished substrate. The substrate transfer mechanism includes a substrate to-be-polished receiver for receiving the substrate to be polished, and a polished substrate receiver for receiving the substrate which has been polished.

Abstract: A polishing apparatus has a top ring configured to hold a semiconductor wafer on a substrate holding surface, and a pushser configured to deliver the semiconductor wafer to the top ring and receive the semiconductor wafer from the top ring. The pushser includes a push stage having a substrate placement surface on which the semiconductor wafer is placed and an air cylinder configured to vertically move the push stage. The pushser also includes a high-pressure fluid port configured to eject a high-pressure fluid toward the semiconductor wafer.

Abstract: A lower unit for a glass polishing system includes a support installed to a rotatable turntable, and a carrier having a supporting part for supporting a glass to be polished, and a placing part formed in a surface opposite to the supporting part and fixed and placed to the support.

Abstract: A semiconductor manufacturing apparatus includes a supporting unit for supporting a semiconductor wafer received from a CMP apparatus and a vacuuming system for holding the wafer on the supporting unit. The vacuuming is applied only in a peripheral area of the wafer. In the peripheral area of the wafer, any circuit such as interconnections and devices are not manufactured. When the wafer is released by supplying gas to the vacuumed space, even if static electricity occurs, the electronic circuit to be manufactured on the wafer does not harmed, because the static electricity occurs only in the peripheral area where any circuit does not exist.

Abstract: The present invention provides a polishing head 1 comprising a carrier 3, a guide ring 4, a dress ring 5, and a head body 2, wherein the head body 2 is rotatable, and holds the carrier 3, the guide ring 4, and the dress ring 5; the head body 2 has a reversed-bowl shape and has a hollow 8; the dress ring, and at least the guide ring or the carrier are held by being coupled to a lower brim of the head body via a diaphragm 6; the hollow of the head body is sealed. During polishing, the pressure of the sealed hollow is adjusted with a pressure regulating mechanism 9 communicating with the hollow, thereby elastically deforming the diaphragm. As a result, a wafer W can be polished while the wafer and the dress ring are pressed with a given pressing force against a polishing pad 11 on a turn table 12 with rotating the wafer held by the carrier and the dress ring.

Abstract: The present invention is a compound sliding seal unit of markedly reduced size and height dimensions which is employed as a discrete assembly for both the passage across and the at-will height adjustment of a mounted, rotatable shaft which extends from the atmospheric environment portion into the vacuum environmental portion of an ion implanter apparatus. The extended, rotatable shaft is typically fashioned as either a rotatable hollow tube or conduit (suitable for the passage of electrical components) and/or as a rotatable support suitable for the mounting of a pivotal scanning radial arm translation system. The manner of construction and the substantially reduced height dimensions of the compound sliding seal unit permits on-demand changes of height for the mounted, rotatable shaft which extends from the atmospheric environment and extends through the compound unit into the confined and limited spatial volume of a vacuum environment within a conventional ion implantation apparatus.

Abstract: A method of machining a wafer is disclosed, in which the wafer is held by sucking its back-side surface directly onto a suction surface of a chuck table, and the tips of protruding electrodes and a resist layer are cut to make them flush with each other (appendant part cutting step). Next, the wafer is held by sucking the surface of the cut appendant part directly onto the suction surface of the chuck table, and the back-side surface of the wafer is ground (back-side surface grinding step), followed by removing the resist layer. The wafer is held onto the chuck table without using any protective tape but by directly holding the wafer, whereby the wafer can be ground to have a uniform thickness.

Abstract: A chemical mechanical head includes a retaining ring to maintain a substrate beneath the mounting surface during polishing. The retaining ring has a lower portion with a bottom surface for contacting a polishing pad during polishing and made of a first material, such as plastic, and an upper portion made of a second, different material, such as metal.