Abstract: The present invention provides a method and apparatus for achieving conformal step coverage on a substrate by PVD. A target provides a source of material to be sputtered by a plasma and then ionized. Ionization is facilitated by maintaining a sufficiently dense plasma using, for example, an inductive coil. The ionized material is then deposited on the substrate which is biased to a negative voltage. A signal provided to the target during processing includes a negative voltage portion and a zero-voltage portion. During the negative voltage portion, ions are attracted to the target to cause sputtering. During the zero-voltage portion, sputtering from the target is terminated while the bias on the substrate cause reverse sputtering therefrom. Accordingly, the negative voltage portion and the zero-voltage portion are alternated to cycle between a sputter step and a reverse sputter step.

Abstract: A system and method for transferring a wafer between chambers is provided. Generally, the system includes a first chamber abutting a first wall of a transfer chamber. The transfer chamber includes at least a first transfer robot having a central axis of rotation disposed therein. The first chamber includes a substrate receiving member that is adapted to support the wafer centered on a central axis of the wafer receiving member. The support member is positioned such that a line defined between the central axis of the robot and central axis of the wafer receiving member is disposed at an acute angle relative to the first sidewall.

Abstract: The temperature controlled gas distribution plate of the present invention includes a liquid cooling passage, with inlet and outlet ports, that is formed within the gas distribution plate. In the preferred embodiment, the plate is formed with an upper passage cover and a lower base having a liquid passage channel formed within the side walls thereof. The cover and base are welded together to form a sealed liquid passage within the plate through which the liquid coolant flows.

Abstract: A sputtering coil for a plasma chamber in a semiconductor fabrication system is provided. The sputtering coil couples energy into a plasma and also provides a source of sputtering material to be sputtered onto a workpiece from the coil to supplement material being sputtered from a target onto the workpiece. Alternatively a plurality of coils may be provided, one primarily for coupling energy into the plasma and the other primarily for providing a supplemental source of sputtering material to be sputtered on the workpiece.

Abstract: The present invention provides an electrochemical deposition system that is designed with a flexible architecture that is expandable to accommodate future designs and gap fill requirements and provides satisfactory throughput to meet the demands of other processing systems. The electrochemical deposition system generally comprises a mainframe having a mainframe wafer transfer robot, a loading station disposed in connection with the mainframe, one or more processing cells disposed in connection with the mainframe, and an electrolyte supply fluidly connected to the one or more electrical processing cells. Preferably, the electrochemical deposition system includes a spin-rinse-dry (SRD) station disposed between the loading station and the mainframe, a rapid thermal anneal chamber attached to the loading station, and a system controller for controlling the electrochemical deposition process and the components of the electrochemical deposition system.

Abstract: The present invention provides a method and apparatus for achieving conformal step coverage on a substrate by PVD. A target provides a source of material to be sputtered by a plasma and then ionized. Ionization is facilitated by maintaining a sufficiently dense plasma using, for example, an inductive coil. The ionized material is then deposited on the substrate which is biased to a negative voltage. A signal provided to the target during processing includes a negative voltage portion and a zero-voltage portion. During the negative voltage portion, ions are attracted to the target to cause sputtering. During the zero-voltage portion, sputtering from the target is terminated while the bias on the substrate cause reverse sputtering therefrom. Accordingly, the negative voltage portion and the zero-voltage portion are alternated to cycle between a sputter step and a reverse sputter step.

Abstract: Apparatus for promoting heat transfer between a first volume (chamber volume) and a second volume (expandable, substrate support platform volume). Specifically, the apparatus comprises: a chamber defining a chamber volume that contains a chamber atmosphere, e.g., a partial vacuum; a substrate support platform that defines an expandable volume that contains a heat transfer medium, e.g., air; and a seal that isolates the chamber volume from the heat transfer medium. The substrate support platform further comprises: a substrate support platen that has a first surface located within the chamber volume and a second surface located within the expandable volume; a housing sealed to the second surface of the substrate support platen; and a expandable member such as a bellows, attached to the housing, to provide for expansion of the expandable volume that is defined by the housing and the bellows. The housing is typically fabricated of metal and the substrate support is typically fabricated of ceramic.

Abstract: The present invention generally provides a system for processing substrates having a carrier disposed primarily in at least one processing chamber and at least one shuttle for transferring substrates between the processing chamber and a load lock chamber. A plurality of processing chambers, load lock chambers, and other chambers can be joined to create a series of modular chambers through which the substrates are processed. Preferably, the carrier is only exposed to the processing environment, i.e., the carrier does not shuttle into a non-processing chamber. Thus, during continuous sequential processing of substrates, thermal cycling of the carrier is reduced. The carrier is reversibly moved within the processing chamber along a track. Multiple processing zones separated by partitions allow a plurality of processing regimes to occur within the same processing chamber.

Abstract: The invention provides a substrate support member and a purge guide for directing purge gas past the edge of a substrate and towards the outer perimeter of the chamber. The purge guide includes a plurality of holes disposed around the inner perimeter thereof to provide a purge gas passage and to prevent purge gas from interfering with the deposition chemistry on the surface of the substrate. A substrate support member is also provided having a vacuum chuck for securing a substrate to the upper surface thereof. The substrate support member preferably includes a shoulder on which the purge guide is supported during processing. The invention also provides a method for shielding an edge of a substrate by flowing a purge gas adjacent the edge of the substrate and then through a plurality of purge holes on a purge guide.

Abstract: A recessed coil for a plasma chamber in a semiconductor fabrication system is provided. Recessing the coil reduces deposition of material onto the coil which in turn leads to a reduction in particulate matter shed by the coil onto the workpiece.

Abstract: A method of depositing titanium nitride by chemical vapor deposition in a chamber having several design features directed to the conductive nature of titanium nitride, particularly when a plasma treatment step is performed after the thermal deposition of the film. Preferably, during the post-deposition plasma treatment, RF power is applied only to the showerhead counter-electrode and none to the pedestal supporting the wafer, thereby preventing charging of the wafer.

Abstract: An RF plasma etch reactor having an etch chamber with electrically conductive walls and a protective layer forming the portion of the walls facing the interior of the chamber. The protective layer prevents sputtering of material from the chamber walls by a plasma formed within the chamber. The etch reactor also has an inductive coil antenna disposed within the etch chamber which is used to generate the plasma by inductive coupling. Like the chamber walls, the inductive coil antenna is constructed to prevent sputtering of the material making up the antenna by the plasma. The coil antenna can take on any configuration (e.g. location, shape, orientation) that is necessary to achieve a desired power deposition pattern within the chamber. Examples of potential coil antenna configurations for achieving the desired power deposition pattern include constructing the coil antenna with a unitary or a segmented structure.

Abstract: The present invention provides an electro-chemical deposition system that is designed with a flexible architecture that is expandable to accommodate future designs and gap fill requirements and provides satisfactory throughput to meet the demands of other processing systems. The electro-chemical deposition system generally comprises a mainframe having a mainframe wafer transfer robot, a loading station disposed in connection with the mainframe, one or more processing cells disposed in connection with the mainframe, and an electrolyte supply fluidly connected to the one or more electrical processing cells. Preferably, the electro-chemical deposition system includes a spin-rinse-dry (SRD) station disposed between the loading station and the mainframe, a rapid thermal anneal chamber attached to the loading station, and a system controller for controlling the electro-chemical deposition process and the components of the electro-chemical deposition system.

Abstract: A recessed coil for a plasma chamber in a semiconductor fabrication system is provided. Recessing the coil reduces deposition of material onto the coil which in turn leads to a reduction in particulate matter shed by the coil onto the workpiece.

Abstract: A method of depositing titanium nitride by chemical vapor deposition in a chamber having several design features directed to the conductive nature of titanium nitride, particularly when a plasma treatment step is performed after the thermal deposition of the film. Preferably, during the post-deposition plasma treatment, RF power is applied only to the showerhead counter-electrode and none to the pedestal supporting the wafer, thereby preventing charging of the wafer.

Abstract: A method and apparatus for providing integrated bake and chill thermal cycling applied to a material substrate is provided. The apparatus is a module comprising an integrated bake and chill plate with one or more fluid channels in a generally spiraling arrangement. The fluid channels have inlets and outlets near the center and perimeter of the integrated bake and chill plate. Additionally, the fluid channels can have microchannels through portions thereof. The module can also comprise one or more thermoelectric devices, a thermally conductive plate on which the substrate directly or indirectly rests, a printed circuit board, and a variable power source. The integrated bake and chill plate, the thermally conductive plate and the thermoelectric devices are all in thermal contact with each other.

Abstract: The present invention provides a method and apparatus for achieving conformal step coverage on a substrate by PVD. A target provides a source of material to be sputtered by a plasma and then ionized. Ionization is facilitated by maintaining a sufficiently dense plasma using, for example, an inductive coil. The ionized material is then deposited on the substrate which is biased to a negative voltage. A signal provided to the target during processing includes a negative voltage portion and a zero-voltage portion. During the negative voltage portion, ions are attracted to the target to cause sputtering. During the zero-voltage portion, sputtering from the target is terminated while the bias on the substrate cause reverse sputtering therefrom. Accordingly, the negative voltage portion and the zero-voltage portion are alternated to cycle between a sputter step and a reverse sputter step.

Abstract: A method for controlling the operation of a magnetron source for sputtering a surface of a target in a vacuum chamber, the method including the steps of: during a low pressure phase of sputtering, causing a magnetic field generated by a the magnetron source to be confined primarily to an inner region of the surface of the target so as to reduce leakage of electrons away from the target during sputtering; and during a subsequent high pressure phase of sputtering, causing the magnetic field generated by the magnet assembly to extend into the outer region of the surface of the target so as to sputter material from the outer region of the surface of the target. The pressure of the high pressure phase of sputtering is higher than the pressure of the low pressure phase of sputtering.