Abstract: Embodiments of the present invention generally relate to sputtering of materials. In particular, the invention relates to sputtering voltage used during physical vapor deposition of large area substrates to prevent arcing. One embodiment of the invention describes an apparatus for sputtering materials on rectangular substrates at a voltage less than 400 volts, that comprises a sputtering target; wherein the target is biased at a voltage less than 400 volts during sputtering materials on the rectangular substrates, a grounded shield surrounding the sputtering target, wherein the shortest distance between the grounded shield and the sputtering target is less than the plasma dark space thickness, a magnetron in the back of the sputtering target, where in the edge of the magnetron does not overlap the grounded shield, and an antenna structure placed between the sputtering target and the substrate, wherein the antenna structure is grounded during sputtering.

Abstract: The present invention generally provides an apparatus and method for processing a surface of a substrate in physical vapor deposition (PVD) chamber that has an increased anode surface area to improve the deposition uniformity on large area substrates. In general, aspects of the present invention can be used for flat panel display processing, semiconductor processing, solar cell processing, or any other substrate processing. In one aspect, the processing chamber contains one or more anode assemblies that are used to increase and more evenly distribute the anode surface area throughout the processing region of the processing chamber. In one aspect, the anode assembly contains a conductive member and conductive member support. In one aspect, the processing chamber is adapted to allow the conductive member to be removed from the processing chamber without removing any major components from the processing chamber.

Abstract: A rectangular magnetron placed at the back of a rectangular sputtering target for coating a rectangular panel and having magnets of opposed polarities arranged to form a gap therebetween corresponding to a plasma track adjacent the target which extends in a closed serpentine or spiral loop. The spiral may have a large number of wraps and the closed loop may be folded before wrapping. The magnetron has a size only somewhat less than that of the target and is scanned in the two perpendicular directions of the target with a scan length of, for example, about 100 mm for a 2 m target corresponding to at least the separation of the gap between parallel portions of the loop. A central ferromagnetic shim beneath some magnets in the loop may compensate for vertical droop. The magnetron may be scanned in two alternating double-Z patterns rotated 90° between them.

Abstract: The present invention generally provides an apparatus and method for processing a surface of a substrate in physical vapor deposition (PVD) chamber that has an increased anode surface area to improve the deposition uniformity on large area substrates. In general, aspects of the present invention can be used for flat panel display processing, semiconductor processing, solar cell processing, or any other substrate processing. In one aspect, the processing chamber contains one or more adjustable anode assemblies that are used to increase and more evenly distribute the anode surface area throughout the processing region of the processing chamber. In one aspect, the one or more adjustable anode assemblies are adapted to exchange deposited on anode surfaces with new, un-deposited on, anode surfaces without breaking vacuum.

Abstract: The present invention generally provides an apparatus and method for processing a surface of a substrate in physical vapor deposition (PVD) chamber that has an increased anode surface area to improve the deposition uniformity on large area substrates. In general, aspects of the present invention can be used for flat panel display processing, semiconductor processing, solar cell processing, or any other substrate processing. In one aspect, the processing chamber contains one or more anode assemblies that are used to increase and more evenly distribute the anode surface area throughout the processing region of the processing chamber. In one aspect, the anode assembly contains a conductive member and conductive member support. In one aspect, the processing chamber is adapted to allow the conductive member to be removed from the processing chamber without removing any major components from the processing chamber.

Abstract: A load lock chamber and method for regulating the temperature of substrates positioned within a chamber are provided. In one embodiment, the load lock chamber is configured to remove gases heated during venting of the load lock chamber. In another embodiment, the load lock chamber is configured to provide a cross flow of vent gases. In yet another embodiment, the load lock chamber includes a resistive heating element configured to uniformly head substrates positioned within the load lock chamber.

Abstract: A physical vapor deposition chamber, which includes a sputtering target, a magnetron disposed on a back side of the sputtering target, a metal sheet disposed between at least a portion of the magnetron and the sputtering target to reduce the effect of the magnetic strength of the portion of the magnetron on the sputtering target and a substrate support for holding a substrate.

Abstract: Embodiments of the invention provide a method of welding sputtering target tiles to form a large sputtering target. Embodiments of a sputtering target assembly with welded sputtering target tiles are also provided.

Abstract: A power supply for use in a physical vapor deposition chamber having a target and a substrate support, comprising a power source configured to bias the target with a sputtering voltage relative to the substrate support and configured to bias the target with a reverse voltage about 10 or more times for a period of about one second after an arc is detected inside the physical vapor deposition chamber

Abstract: A target assembly including a plurality of target tiles bonded to a backing plate by adhesive, for example of indium or conductive polymer, filled into recesses in the backing plate formed beneath each of the target tiles. A sole peripheral recess formed as a rectangular close band may be formed inside the tile periphery. Additional recesses may be formed inside the peripheral recess, preferably symmetrically arranged about perpendicular bisectors of rectangular tiles. The depth and width of the recesses may be varied to control the amount of stress and the stress direction.

Abstract: A sputter reactor configured for magnetron sputtering from a rectangular target onto a rectangular panel and including multiple magnetrons independently scannable across the back of the target. In one embodiment, the magnetrons scan only along paths parallel to one axis. A system controller may control actuators providing the mechanical movement and also control the amount of power delivered to the target in synchronism to the mechanical movement. The invention also includes scanning a magnetron in a rectangular path about the back of the rectangular target.

Abstract: A target assembly composed of multiple target tiles bonded in an array to a backing plate of another material. The edges of the tile within the interior of the array are formed with complementary beveled edges to form slanted gaps between the tiles. The gaps may slant at an angle of between 10° and 55°, preferably 15° and 45°, with respect to the target normal. The facing sides of tiles may be roughened by bead blasting, for both perpendicular and sloping gaps. The area of the backing plate underlying the gap may be roughened or may coated or overlain with a region of the material of the target, for both perpendicular and sloping gaps.

Abstract: Embodiments of the present invention generally relate to sputtering targets used in semiconductor manufacturing. In particular, the invention relates to bonding the sputtering target to a backing plate that supports the sputtering target in a deposition chamber. In one embodiment, a method of bonding at least one sputtering target tile to a backing plate comprises providing an elastomeric adhesive layer between the at least one sputtering target tile and the backing plate, and providing at least one metal mesh within the elastomeric adhesive layer, wherein at least a portion of the at least one metal mesh contacts both the at least one sputtering target tile and the backing plate, and the at least a portion of the at least one metal mesh is made of metal wire with diameter greater than 0.5 mm.

Abstract: A target assembly composed of multiple target tiles bonded in an array to a backing plate of another material. The edges of the tile within the interior of the array are formed with complementary structure edges to form a gap between the tiles having at least a portion that is inclined to the target normal. The gap may be simply beveled and slant at an angle of between 10° and 55°, preferably 15° and 50°, with respect to the target normal or they may be convolute with one portion horizontal or otherwise inclined to prevent a line of sight from the bottom to top. The area of the backing plate underlying the gap may be coated or overlain with a foil of the material of the target, for both perpendicular and sloping gaps, and have a polymeric foil adjacent an elastomeric bonding layer to exclude bonding material from the gap.

Abstract: Embodiments of the present invention generally provide an apparatus for providing a uniform thermal profile to a plurality of large area substrates during thermal processing. In one embodiment, an apparatus for thermal processing large area substrates includes a chamber having a plurality of processing zones disposed therein that are coupled to a lift mechanism. The lift mechanism is adapted to vertically position the plurality of processing zones within the chamber. Each processing zone further includes an upper heated plate, a lower heated plate adapted to support a first substrate thereon and an unheated plate adapted to support a second substrate thereon, wherein the unheated plate is disposed between the upper and lower heated plates.

Abstract: Embodiments of an end effector assembly for a substrate robot are provided herein. In one embodiment, the end effector assembly includes a wrist and a first and a second end effector coupled to the wrist in a spaced apart relationship. The first end effector includes a base coupled to the wrist and a tip coupled to the base opposite the wrist. The base and the tip may be made of the same or different materials. The first and the second end effectors may have different resonant frequencies to minimize vibration. Optionally, a low emissivity coating may be provided on the first and second end effector. The low emissivity coating may further have a plurality of stress relief grooves to reduce or prevent flaking of the coating due to differences in rates of thermal expansion between the coating and the underlying end effector.

Abstract: A susceptor is formed with a cavity having a tapered surface and a receiving surface. The gradient ? of the tapered surface with respect to the receiving surface is set to at least 5° and less than 30°, so that a semiconductor wafer received by the susceptor can be located on the receiving surface through the tapered surface while the semiconductor wafer can be protected against excess stress also when the surface of the wafer abruptly thermally expands due to flashlight irradiation and can be prevented from cracking in thermal processing. Thus provided are a thermal processing susceptor and a thermal processing apparatus capable of preventing a substrate from cracking in thermal processing.

Abstract: In a thermal processing apparatus (1), an upper opening (60) is closed by a transparent plate (61) and a light emitting part (5) emits light through the upper opening (60). Also provided are a susceptor (72) for supporting a substrate (9), a hot plate (71) for heating the susceptor (72) and a cover member (21) between the transparent plate (61) and the susceptor (72). The susceptor (72) has a recessed portion whose depth is larger than the thickness of the substrate (9), a lower surface of the substrate (9) is supported by a bottom surface of the recessed portion, and a periphery of the substrate (9) is surrounded by the side wall portion of the recessed portion. During processing of the substrate (9), the cover member (21) is moved down and brought into contact with an upper end of the side wall portion to close the recessed portion.

Abstract: Embodiments of the invention generally provide an apparatus and a method for providing a uniform thermal profile to a plurality of substrates during heat processing. In one embodiment, a cassette containing one or more heated substrate supports is moveably disposed within a heating chamber having an about uniform thermal profile therein to more uniformly heat the substrates.

Abstract: In a first aspect, a first apparatus is provided for heating substrates. The first apparatus includes (1) a chamber having a bottom portion and a top portion; (2) a plurality of heated supports disposed within the chamber to support at least two substrates thereon; and (3) a heater disposed within the chamber between a sidewall of the chamber and the plurality of substrate supports and having an edge region and a center region. The heater is adapted to produce more heat within the edge region than within the center region of the heater. Numerous other aspects are provided.