Abstract: The barrel type susceptor for use in the semiconductor epitaxial growth is characterized in that a face plate 5 of a susceptor main body 2 having the shape of a truncated cone is partitioned into two or more in a longitudinal direction thereof, each partition being provided with a wafer mounting concave portion 6a, 6b, 6c on which a wafer is laid, and the inclination angle ?a, ?b, ?c of a bottom face 6a1, 6b1, 6c1 of the concave portion for each partition to the vertical line is gradually decreased in each partition from the upper part to the lower part.

Abstract: Generally, a substrate support member for supporting a substrate is provided. In one embodiment, a substrate support member for supporting a substrate includes a body coupled to a lower shield. The body has an upper surface adapted to support the substrate and a lower surface. The lower shield has a center portion and a lip. The lip is disposed radially outward of the body and projects towards a plane defined by the first surface. The lip is disposed in a spaced-apart relation from the body. The lower shield is adapted to interface with an upper shield disposed in a processing chamber to define a labyrinth gap that substantially prevents plasma from migrating below the member. The lower shield, in another embodiment, provides the plasma with a short RF ground return path.

Abstract: A substrate treatment method for treating a substrate by supplying a treatment liquid to the substrate while rotating the substrate. The method comprises the steps of: performing a first substrate rotation process for rotating the substrate while clamping the substrate by a first clamping member set; performing a second substrate rotation process after the first substrate rotation step for rotating the substrate while clamping the substrate by the first clamping member set and a second clamping member set provided separately from the first clamping member set; and performing a third substrate rotation process after the second substrate rotation step by unclamping the substrate from the first clamping member set for rotating the substrate while clamping the substrate by the second clamping member set.

Abstract: A semiconductor processing chamber having a silicon containing pre-coat is provided. The chamber includes a top electrode in communication with a power supply and a processing chamber defined within a base, a sidewall extending from the base, and a top disposed on the sidewall. The processing chamber has an outlet enabling removal of fluids within the processing chamber and includes a substrate support where an outer surface of the substrate support coated with the removable silicon containing coating, wherein the silicon containing coating is a compound consisting essentially of silicon and one of bromine and chlorine. The chamber includes an inner surface defined by the base, the sidewall and the top, where the inner surface is coated with a removable silicon containing coating.

Abstract: Embodiments of the present invention provide an apparatus for constraining and supporting the lift pins to prevent or minimize lateral movement of the lift pins that causes substrate hand-off problems and associated degradation in substrate processing characteristics and results. In one embodiment, a lift pin assembly for manipulating a substrate above a support surface of a substrate support comprises a plurality of lift pins movable between an up position and a down position. The lift pins include top ends and bottom ends. The top ends are configured to be lifted above the support surface of the substrate support to contact a bottom surface of the substrate in the up position. The top ends are configured to be positioned at or below the support surface of the substrate support in the down position.

Abstract: A wafer chuck is configured to hold a wafer efficiently for spin process cleaning of wafer edges and back sides. A first group of retractable tips extend to hold the wafer during a first portion of the cleaning period. A second group of retractable tips extend to hold the wafer during a second portion of the cleaning period. Residues left between the tips and the wafer edge areas during the first portion of the cleaning period are removed during the second portion. The change from the first group of tips to the second group of tips occurs while the wafer is rotating.

Abstract: A wafer support system comprising a segmented susceptor having top and bottom sections and gas flow passages therethrough. A plurality of spacers projecting from a recess formed in the top section of the susceptor support a wafer in spaced relationship with respect to the recess. A sweep gas is introduced to the bottom section of the segmented susceptor and travels through the gas flow passages to exit in at least one circular array of outlets in the recess and underneath the spaced wafer. The sweep gas travels radially outward between the susceptor and wafer to prevent back-side contamination of the wafer. The gas is delivered through a hollow drive shaft and into a multi-armed susceptor support underneath the susceptor. The support arms conduct the sweep gas from the drive shaft to the gas passages in the segmented susceptor. The gas passages are arranged to heat the sweep gas prior to delivery underneath the wafer.

Abstract: To move an article in and out of plasma during plasma processing, the article is rotated by a first drive around a first axis, and the first drive is itself rotated by a second drive. As a result, the article enters the plasma at different angles for different positions of the first axis. The plasma cross-section at the level at which the plasma contacts the article is asymmetric so that those points on the article that move at a greater linear velocity (due to being farther from the first axis) move longer distances through the plasma. As a result, the plasma processing time becomes more uniform for different points on the article surface. In some embodiments, two shuttles are provided for loading and unloading the plasma processing system. One of the shuttles stands empty waiting to unload the processed articles from the system, while the other shuttle holds unprocessed articles waiting to load them into the system.

Abstract: A device for liquid treatment of a defined area of a wafer-shaped article, especially of a wafer, in which a mask is kept at a defined short distance to the wafer-shaped article such that liquid can be retained between the mask and the defined area of the wafer-shaped article by capillary forces.

Abstract: A substrate support assembly positively secures a substrate holder support to a rotation shaft with respect to rotationally applied forces. A substrate holder support is configured to have an opening in a socket into which, when aligned with an indentation in the rotational shaft to form a passage, a retaining member is removably inserted to engage both the socket opening and the shaft indentation. Methods of rotating a substrate while minimizing rotational slippage of the substrate holder support with respect to the shaft are also provided.

Abstract: A multi-stage type processing apparatus which can be positioned in a limited space without having a complicated driving mechanism, includes processing units which are stacked in a multi-stage state in the vertical direction. Each processing unit has a cup surrounding a substrate and a chuck for retaining and rotating a substrate, and the cup can be elevated and lowered with respect to the chuck. A cylinder unit is contracted and thereby all the cups are unitarily lowered, so that the top surface of the chuck is located in a slightly upper position with respect to the top surface of the cup. In this state, a substrate is mounted on the chuck and attracted. Next, the cylinder unit is extended and thereby all the cups are unitarily elevated so as to accommodate the substrate therein.

Abstract: The invention relates to a drive mechanism for a vacuum treatment apparatus by which substrate holders can be transported around an axis (A—A) from an entrance airlock to an exit airlock. A stationary supporting column (1) is disposed in the center and on it a rotatory drive chamber (6) is borne which has control rods (9) for a rotation and a radial displacement of the substrate holders. In the rotatory drive chamber (6), a motor (4) and rotatory displacement drives for the control rods (9) are arranged on the supporting column (1), the control rods being in active connection each with a corresponding substrate holder.

Abstract: In a substrate vacuum processing chamber, a second inner slit passage door apparatus and method to supplement the normal slit valve and its door at the outside of the chamber. The inner slit passage door, blocks the slit passage at or adjacent the substrate processing location in a vacuum processing chamber to prevent process byproducts from depositing on the inner surfaces of the slit passage beyond the slit passage door and improves the uniformity of plasma in the processing chamber by eliminating a large cavity adjacent to the substrate processing location into which the plasma would otherwise expand.

Abstract: A semiconductor device is inspected and cleaned by applying a vacuum to the area in which the semiconductor device is positioned. Micro-sized particulates that are brushed off the semiconductor device during cleaning are drawn off by the vacuum.

Abstract: A semiconductor processing chamber having a plurality of ribs on an exterior surface of the chamber is provided. The ribs are positioned relative to the chamber such that shadows cast into the chamber by the ribs are offset from one another, thus more uniformly distributing radiant energy entering the chamber. In one embodiment, the ribs are positioned on the exterior surface of the chamber so that they have dissimilar radial distances from a center of the chamber. When a substrate rotates within the chamber, shadows produced by the ribs on a first side of the chamber fall substantially between secondary shadows produced by the ribs on a second side of the chamber. Likewise, shadows produced by the ribs on the second side of the chamber fall substantially between the secondary shadows produced by the ribs on the first side of the chamber.

Abstract: Particle beam systems and methods for interacting with a workpiece according to this invention include a work stage assembly and a first particle beam source. The work stage assembly is adapted a) for supporting a workpiece, b) for translating along a first axis, c) for translating along a second axis perpendicular to the first axis, and d) for rotating about a third axis perpendicular to both the first axis and the second axis. The work stage assembly has a work stage axis substantially parallel to the third axis. The first particle beam source for interacting with the workpiece is supported by the work stage assembly. The first particle beam source has a first particle beam axis. In one embodiment, the first particle beam source is oriented so that the first particle beam axis forms an angle with the third axis.

Abstract: A method for spinning a wafer to enable rinsing and drying is provided. The method includes engaging the wafer at a wafer processing plane and spinning the wafer. The method further includes moving a wafer backside plate from a first position to a second position as spinning of the wafer proceeds to an optimum spinning speed. The second position defines a reduced gap between an under surface of the wafer and a top surface of the wafer backside plate. The method also includes repositioning the wafer backside plate from the second position to the first position as the spinning reduces in speed. The first position defines an enlarged gap to enable loading and unloading of the wafer from the engaged position.

Abstract: A planet system workpiece support for a vacuum treatment apparatus includes a sun system rotatable in the vacuum treatment apparatus about a sun system axle to be coupled to a drive. At least one planet system is rotatable on planet axle and is supported on the sun system. The planet system has a driving coupling for driving the planet system and the support has at least one moon system supported on the planet system and rotatable about a moon axle with a driving connection to the sun system. At least one workpiece is received on the moon system and the driving connection is established, at least during operation, uninterruptedly between sun system and moon system.

Abstract: The invention relates to a device for depositing especially, crystalline layers onto one or more, especially, also crystalline substrates in a process chamber using reaction gases which are guided into said process chamber, where they undergo pyrolytic reaction. The device has a heatable support plate wherein at least one substrate holder lies loosely, especially rotationally, with its surface flush with the surroundings. A compensation plate which adjoins the at least one substrate holder, following the contours of the same, is provided on the support plate in order to keep the isothermal profile on the support plate as flat as possible.

Abstract: A wafer chuck is configured to hold a wafer efficiently for spin process cleaning of wafer edges and back sides. A first group of retractable tips extend to hold the wafer during a first portion of the cleaning period. A second group of retractable tips extend to hold the wafer during a second portion of the cleaning period. Residues left between the tips and the wafer edge areas during the first portion of the cleaning period are removed during the second portion. The change from the first group of tips to the second group of tips occurs while the wafer is rotating.

Abstract: An annular receptacle is described, particularly for a rotating carrier for receiving a disk-shaped object such as a semiconductor.

Abstract: A device (1) for treating objects, in particular silicon wafers (2), with a fluid (3), comprising a container (4) that holds the fluid (3); a rotatable carrying arrangement (5) for accommodation of the objects to be treated, which is disposed at least partially in the container (4); and a rotatably drivable shaft, which is run on at least one bearing (13, 14) and joined to the carrying arrangement (5); with the bearing (13, 14) including a first bearing member (22), which is joined to the shaft, and a second bearing member (24), which adjoins the first bearing member (22) and contains superconductive material; with the first bearing member (22) being kept spaced from the second bearing member (24) by magnetic forces.

Abstract: A system for cleaning a semiconductor substrate is provided. The system includes transducers for generating acoustic energy oriented in a substantially perpendicular direction to a surface of a semiconductor substrate and an acoustic energy oriented in a substantially parallel direction to the surface of the semiconductor substrate. Each orientation of the acoustic energy may be simultaneously or alternately generated.

Abstract: Apparatus for the processing of materials involving placing a material either placed between an radio-frequency electrode and a ground electrode, or which is itself one of the electrodes. This is done in atmospheric pressure conditions. The apparatus effectively etches or cleans substrates, such as silicon wafers, or provides cleaning of spools and drums, and uses a gas containing an inert gas and a chemically reactive gas.

Abstract: A substrate treatment method for treating a substrate by supplying a treatment liquid to the substrate while rotating the substrate. The method comprises the steps of: performing a first substrate rotation process for rotating the substrate while clamping the substrate by a first clamping member set; performing a second substrate rotation process after the first substrate rotation step for rotating the substrate while clamping the substrate by the first clamping member set and a second clamping member set provided separately from the first clamping member set; and performing a third substrate rotation process after the second substrate rotation step by unclamping the substrate from the first clamping member set for rotating the substrate while clamping the substrate by the second clamping member set.

Abstract: A focus ring assembly, configured to be coupled to a substrate holder in a plasma processing system, comprises a focus ring having one or more wear indicators for determining the lifetime of the focus ring, wherein the coupling of the focus ring to the substrate holder facilitates auto-centering of the focus ring in the plasma processing system. For example, a centering ring mounted on the substrate holder can comprise a centering feature configured to couple with a mating feature on the focus ring.

Abstract: An etching/cleaning apparatus is provided, which makes it possible to effectively remove an unnecessary material or materials existing on a semiconductor wafer without damaging the device area with good controllability. The apparatus comprises (a) a rotating means for holding a semiconductor wafer and for rotating the wafer in a horizontal plane; the wafer having a device area and a surface peripheral area on its surface; the surface peripheral area being located outside the device area; and (b) an edge nozzle for emitting an etching/cleaning liquid toward a surface peripheral area of the wafer. The etching/cleaning liquid emitted from the edge nozzle selectively removes an unnecessary material existing in the surface peripheral area.

Abstract: A method and apparatus for processing a thin film on a substrate. The method involves locating the substrate in a first rotational position a location opposed to a process station. The process station has a first axis and is arranged for processing the substrate about that axis. The substrate location is symmetrical about a second axis parallel to but offset from the first axis. The substrate is rotated about an axis generally orthogonal and passing through the wafer location to a second rotational position after an initial process and further processing takes place when the substrate is in the second rotational position.

Abstract: A multi-station deposition apparatus capable of simultaneous processing multiple substrates using a plurality of stations, where a gas curtain separates the stations. The apparatus further comprises a multi-station platen that supports a plurality of wafers and rotates the wafers into specific deposition positions at which deposition gases are supplied to the wafers. The deposition gases may be supplied to the wafer through single zone or multi-zone gas dispensing nozzles.

Abstract: A vacuum processing device includes a driven body 122 provided inside a vacuum processing chamber 104, a driving means 126 provided outside the vacuum processing chamber 104 and a drive shaft 124 connecting the driven body 122 to the driving means 126. A first annular body 152 is secured to the drive shaft 124 and a second annular body 150 is rotatably supported by the first annular body 152. A bellows 148 that airtightly seals the periphery of the drive shaft 124 is provided so as to connect the second annular body 150 with the inner wall of the vacuum processing chamber 104. In this structure, the bellows 148 is allowed to move as one body with the drive shaft 124 during vertical motion of the drive shaft 124 but is made to stay in place during rotational motion of the drive shaft 124. Thus, the drive shaft, which engages in vertical motion and rotational motion, is airtightly sealed by the bellows.

Abstract: Systems and methods for epitaxial deposition. The reactor includes a hot wall process cavity enclosed by a heater system, a thermal insulation system, and chamber walls. The walls of the process cavity may comprises a material having a substantially similar coefficient thermal expansion as the semiconductor substrate, such as quartz and silicon carbide, and may include an isothermal or near isothermal cavity that may be heated to temperatures as high as 1200 degrees C. Process gases may be injected through a plurality of ports, and are capable of achieving a fine level of distribution control of the gas components, including the film source gas, dopant source gas, and carrier gas. The gas supply system includes additional methods of delivering gas to the process cavity, such as through temperature measurement devices, and through a showerhead.

Abstract: An article (e.g. a semiconductor wafer) is held in an article holder by means of a number of gas flows emitted from gas vortex chambers. Some of the gas flows act to cool an adjacent article portion more than the other gas flows. For example, some of the vortex chambers emit more gas per unit of time than the other chambers. More cooling is provided to those portions of the article which are heated more during processing. Greater temperature uniformity can be achieved.

Abstract: A process chamber for processing or inspecting a substrate such as a semiconductor wafer and the like includes a internal chamber employing dynamic seals at the interface of relatively moving elements. In one embodiment, the internal chamber has a first element, such as a lid or cover, and a second element, such as the body of the chamber. The first element and the second element meet at the interface. The internal chamber may further include a substrate support, mounted inside the internal chamber, supporting a substrate. A first movement system may produce at least one type of relative movement between the first element and the second element. A second movement system may produce second relative movement between the second element and the substrate support. The resulting structure allows movement of the chamber, while maintaining pressure inside the chamber.

Abstract: The present invention provides a rotating shaft that can extend between two regions having different ambient pressures. The rotating shaft can include a rotatable hollow outer shell that is coupled to a proximal portion of an inner shaft with a limited number of contact points. A plurality of thermal breaks disposed between the inner shaft and the hollow outer shell impede heat transfer between these two components. A rotary seal coupled to the distal portion of the inner shaft preserves the pressure differential between the two regions. Further, a heat sink removes heat transferred to the seal to ensure that the temperature of the seal remains within a range suitable for its operation. The rotating shaft of the invention can be utilized, for example, in an ion implantation system by the coupling of the outer shell to a wafer holder to position and orient a wafer in a path of an ion beam.

Abstract: An epitaxial growth furnace is provided for effecting the formation of an epitaxial layer on the surface of a semiconductor wafer by CVD in a reaction chamber of the furnace. The furnace comprises a wafer holder having an opening for exposing a surface area of the wafer which is subject to epitaxial growth, an opening flange adapted for engagement with a chamfered tapered face of a whole peripheral edge of the wafer on the side of said surface area thereof, and a plurality of jaws for detachably engaging with an outer periphery of the wafer on a back surface side of said surface area.

Abstract: To achieve a uniform coating of a substrate, with an apparatus and a method for coating substrates, according to which the substrate is supported on a substrate holder in such a way that a substrate surface that is to be coated is exposed, and the substrate is rotated together with the substrate holder, a cover can be secured to the substrate holder and together with the substrate holder forms a sealed chamber for the substrate.

Abstract: The invention relates to the technical field of plasma treatment of planar elements such as plates, sheets and wafers in electronics and electrical engineering, and in essence is a device for treating wafers with a plasma jet. The device comprises the following elements mounted in a closed chamber: a drive that effects angular displacement of the holders, which are provided with a common rotary drive, a plasma jet generator, and, mounted outside the closed chamber a manipulator and storage devices for the wafers. The wafer to be treated is picked up by the manipulator from the storage device and placed in the holder which together with the wafer passes over the plasma jet generator used for the treatment. The cycle may be repeated a predetermined number of times.

Abstract: A film-forming device with a substrate rotating mechanism includes a susceptor 30 in the form of a circular disk; a base plate 6 positioned below the susceptor 30 and rotatably retaining the susceptor 30; a revolution generating section 5 rotating the susceptor 30 at the outer periphery of the susceptor 30; a plurality of substrate tray retaining sections 23 arranged on the susceptor 30; a plurality of annular substrate trays 20 rotatably supported in the corresponding substrate tray retaining sections 23; a rotation generating section 4 rotating the substrate trays 20; and a plurality of substrates W retained in the substrate trays 20. The substrates W are revolved by the rotation of the susceptor 30 and rotated by the rotation of the substrate trays 20 to apply a certain film-forming process. The substrates W are rotated and revolved by one or more revolution generating section 5 and the rotation generating section 4.

Abstract: Provided is a wafer rotary holding apparatus by which a reduced pressure is created on an upper surface of a rotary disk by a simple and easy-to-make mechanism with no need of any of a vacuum source apparatus, a compressed air supply apparatus, a compressed gas supply apparatus and other apparatuses in use; a wafer can be held while rotating with no contact to a rear surface thereof; a degree of pressure reduction can be adjusted with ease and even a thin wafer (of 0.1 mm or less in thickness) can be held while rotating with no deformation; and the wafer with a bowing can be held while rotating with no correction of the bowing. A wafer rotary holding apparatus includes: a rotary disk on which a fluid flow path is formed; a through hole formed in a central section of the rotary disk; and a plurality of wafer rests provided on an upper surface of the rotary disk.

Abstract: The invention relates to a device for depositing layers, particularly crystalline layers, onto substrates. Said device comprises a process chamber arranged in a reactor housing where the floor thereof, comprises at least one substrate holder which is rotatably driven by a gas flow flowing in a feed pipe associated with said floor. Said substrate holder is disposed in a bearing cavity on a gas cushion and held in place thereby. The aim of the invention is to technologically improve the design of a substrate holder which is rotatably mounted in a gas flow, particularly in a linear cross-flowing process chamber. Said bearing cavity is associated with a tray-shaped element arranged below the outflow of the feed pipe.

Abstract: A gas driven rotation apparatus for use with a flow of drive gas includes a base member having an upper surface, a main platter overlying the upper surface of the base member, and a satellite platter overlying the main platter. The apparatus is adapted to direct the flow of drive gas between the upper surface of the base member and the main platter such that the main platter is rotated relative to the base member by the flow of drive gas. At least a portion of the flow of drive gas is directed from between the upper surface of the base member and the main platter to between the main platter and the satellite platter such that the satellite platter is rotated relative to the main platter by the at least a portion of the flow of drive gas.

Abstract: An apparatus for processing a semiconductor wafer or similar article includes a reactor having a processing chamber formed by upper and lower rotors. The wafer is supported between the rotors. The rotors are rotated by a spin motor. A processing fluid is introduced onto the top or bottom surface of the wafer, or onto both surfaces, at a central location. The fluid flows outwardly uniformly and in all directions. A wafer support automatically lifts the wafer, so that it can be removed from the reactor by a robot, when the rotors separate from each other after processing.

Abstract: A substrate processing apparatus injects gas from an injection port formed on a shielding surface of an atmosphere shielding part and sucks a substrate by Bernoulli effect. The substrate is sucked in a state coming into contact with a contact supporting surface of a support member provided on the atmosphere shielding part, and rotated with the upper surface shielded by a shielding surface of the shielding part. A solution supply part supplies a chemical solution to the lower surface of the substrate. Therefore, mist of a processing solution or the processing solution can be reliably prevented from reaching the upper surface of the substrate. Thus provided is a substrate processing apparatus capable of reliably preventing the mist of the processing solution or the processing solution from reaching the upper surface of the substrate.

Abstract: A wafer holder for supporting a wafer within a CVD processing chamber includes a vertically moveable lift ring configured to support the bottom peripheral surface of the wafer, and an inner plug having a top flat surface configured to support the wafer during wafer processing. The lift ring has a central aperture configured to closely surround the inner plug. When a wafer is to be loaded onto the wafer holder, the lift ring is elevated above the inner plug. The wafer is loaded onto the lift ring in the elevated position. Then, the lift ring is maintained in the elevated position for a time period sufficient to allow the wafer temperature to rise to a level that is sufficient to significantly reduce or even substantially prevent thermal shock to the wafer when the wafer is brought into contact with the inner plug. The lift ring is then lowered into surrounding engagement with the inner plug. This is the wafer processing position of the wafer holder.

Abstract: The present invention is generally directed to a system and process for rotating semiconductor wafers in thermal processing chambers, such as rapid thermal processing chambers and chemical vapor deposition chambers. In accordance with the present invention, a semiconductor wafer is supported on a substrate holder which, in turn, is supported on a rotor. During processing, the rotor is magnetically levitated and magnetically rotated by suspension actuators and rotation actuators positioned outside of the chamber.

Abstract: In order to ensure uniform coating of workpieces, workpiece holders carrying said workpieces are rotatably mounted at the edge of a turntable, a plurality of which are fastened in succession at adjustable distances to a drivable shaft. In order to trigger intermittent rotations of the workpiece holders, a driver finger of a driving device engages in each case a drive wheel thereof on each revolution of the turntable, so that the workpiece holders are rotated relative to the turntable through a specific angle in a direction opposite to the direction of rotation of said turntable. In order that no readjustment of the driver finger is required, for example in the case of a change of distances between the turntables, said driver finger is fastened to an extension of a rotating ring, which is mounted on the turntable itself so as to be non-displaceable in the direction of the shaft but rotatable about said shaft.

Abstract: An article which is being processed with plasma is moved during plasma processing so that the motion of the article comprises at least a first rotational motion, a second rotational motion, and a third rotational motion which occur simultaneously. The apparatus that moves the article comprises a first arm rotatable around a first axis, a second arm rotatably attached to the first arm and rotating the article around a second axis, and a rotational mechanism for inducing a rotational motion of the article in addition to, and simultaneously with, the rotation of the first and second arms.

Abstract: A rotary substrate processing apparatus includes a rotor 1 having a holding member for holding a plurality of semiconductor wafers W arranged at appropriate intervals and a motor 4 for rotating the rotor 1. The holding member includes open/close holding rods 3 that are moved to open or close the rotor 1 in inserting the wafers W into the rotor 1 sideways and a plurality of constant-position holding rods 2a to 2d for holding the wafers W in cooperation with the open/close holding rods 3. Among the constant-position holding rods 2a to 2d, at least one constant-position holding rod 2a is equipped with a plurality of press members 5 which move toward respective peripheral portions of the wafers W by centrifugal force due to the rotation of the rotor 1. Consequently, it becomes possible to make the wafers W follow the rotation of the rotor 1 ensurely and also possible to reduce slip between the open/close holding rods 3, the constant-position holding rods 2a to 2d and the wafers W.

Abstract: A wafer chuck for use in a semiconductor process chamber capable of producing an inert gas blanket positioned on the chuck from residual chemical vapor in the chamber is disclosed. A plurality of mounting pins for supporting a wafer is further provided in the upper surface for forming an inert gas into a cavity formed between the wafer and the upper surface of the chuck. A plurality of apertures in a sidewall of the body portion for flowing an inert gas into the lower chamber forming an inert gas blanket blocking a passageway between the upper and lower chambers, thus preventing the wafer from damage by residual chemical vapor in the lower chamber.

Abstract: A wafer support system comprising a segmented susceptor having top and bottom sections and gas flow passages therethrough. A plurality of spacers projecting from a recess formed in the top section of the susceptor support a wafer in spaced relationship with respect to the recess. A sweep gas is introduced to the bottom section of the segmented susceptor and travels through the gas flow passages to exit in at least one circular array of outlets in the recess and underneath the spaced wafer. The sweep gas travels radially outward between the susceptor and wafer to prevent back-side contamination of the wafer. The gas is delivered through a hollow drive shaft and into a multi-armed susceptor support underneath the susceptor. The support arms conduct the sweep gas from the drive shaft to the gas passages in the segmented susceptor. The gas passages are arranged to heat the sweep gas prior to delivery underneath the wafer.