Abstract: Methods and apparatus for forming nitrogen-containing layers are provided herein. In some embodiments, a method of forming a nitrogen-containing layer may include placing a substrate having a first layer disposed thereon on a substrate support of a process chamber; heating the substrate to a temperature of at least about 250 degrees Celsius; and exposing the first layer to a radio frequency (RF) plasma formed from a process gas consisting essentially of ammonia (NH3) and an inert gas while maintaining the process chamber at a pressure of about 10 mTorr to about 40 mTorr to transform at least an upper portion of the first layer into a nitrogen-containing layer.

Abstract: Methods and apparatus for forming nitrogen-containing layers are provided herein. In some embodiments, a method includes placing a substrate having a first layer disposed thereon on a substrate support of a process chamber; heating the substrate to a temperature of at least about 250 degrees Celsius; and exposing the first layer to a radio frequency (RF) plasma formed from a process gas comprising nitrogen while maintaining the process chamber at a pressure of about 10 mTorr to about 40 mTorr to transform at least an upper portion of the first layer into a nitrogen-containing layer. In some embodiments, the process gas includes ammonia (NH3).

Abstract: Embodiments of electrostatic chucks for substrate processing are provided herein. In some embodiments, an electrostatic chuck may include a puck for supporting a substrate, the puck formed from a dielectric material and having a chucking electrode disposed within the puck proximate a support surface of the puck to electrostatically retain the substrate when disposed on the puck; a base having a ring extending from the base to support the puck; and a spacer disposed between the base and the puck to support the puck above the base such that a gap is formed between the puck and the base, wherein the spacer supports the puck proximate a peripheral edge of the puck.

Abstract: Methods and apparatus for forming nitrogen-containing layers are provided herein. In some embodiments, a method of forming a nitrogen-containing layer may include placing a substrate having a first layer disposed thereon on a substrate support of a process chamber; heating the substrate to a temperature of at least about 250 degrees Celsius; and exposing the first layer to a radio frequency (RF) plasma formed from a process gas consisting essentially of ammonia (NH3) and an inert gas while maintaining the process chamber at a pressure of about 10 mTorr to about 40 mTorr to transform at least an upper portion of the first layer into a nitrogen-containing layer.

Abstract: A method and apparatus for plasma processing of substrates is provided. A processing chamber has a substrate support and a lid assembly facing the substrate support. The lid assembly has a plasma source that comprises an inductive coil disposed within a conductive plate, which may comprise nested conductive rings. The inductive coil is substantially coplanar with the conductive plate, and insulated therefrom by an insulator that fits within a channel formed in the conductive plate, or nests within the conductive rings. A field concentrator is provided around the inductive coil, and insulated therefrom by isolators. The plasma source is supported from a conductive support plate. A gas distributor supplies gas to the chamber through a central opening of the support plate and plasma source from a conduit disposed through the conductive plate.

Abstract: A method and apparatus for processing multiple substrates simultaneously is provided. Each substrate may have two major active surfaces to be processed. The apparatus has a substrate handling module and a substrate processing module. The substrate handling module has a loader assembly, a flipper assembly, and a factory interface. Substrates are disposed on a substrate carrier at the loader assembly. The flipper assembly is used to flip all the substrates on a substrate carrier in the event two-sided processing is required. The factory interface positions substrate carriers holding substrates for entry into and exit from the substrate processing module. The substrate processing module comprises a load-lock, a transfer chamber, and a plurality of processing chambers, each configured to process multiple substrates disposed on a substrate carrier.

Abstract: An apparatus for forming a magnetic pattern in a magnetic storage substrate. A chamber comprises a chamber wall that defines an internal volume, a substrate support in the internal volume of the chamber, a gas distributor disposed in a wall region of the chamber facing the substrate support, a compact energy source for ionizing a portion of the process gas provided to the chamber, and a throttle valve having a z-actuated gate member with a sealing surface for covering an outlet portal of the chamber. Ions are accelerated toward the substrate support by an electrical bias, amplifying the ion density of the process gas. A substrate disposed on the substrate support is bombarded by the ions to alter a magnetic property of the substrate surface.

Abstract: A substrate support for a process chamber comprises an electrostatic chuck having a receiving surface to receive the substrate and a gas distributor baseplate below the electrostatic chuck. The gas distributor baseplate comprises a circumferential sidewall having a plurality of gas outlets that are spaced apart from one another to introduce a process gas into the process chamber from around the perimeter of the substrate and in a radially outward facing direction.

Abstract: Methods and apparatus for forming nitrogen-containing layers are provided herein. In some embodiments, a method includes placing a substrate having a first layer disposed thereon on a substrate support of a process chamber; heating the substrate to a temperature of at least about 250 degrees Celsius; and exposing the first layer to a radio frequency (RF) plasma formed from a process gas comprising nitrogen while maintaining the process chamber at a pressure of about 10 mTorr to about 40 mTorr to transform at least an upper portion of the first layer into a nitrogen-containing layer. In some embodiments, the process gas includes ammonia (NH3).

Abstract: Methods and apparatus for forming substrates having magnetically patterned surfaces is provided. A magnetic layer comprising one or more materials having magnetic properties is formed on a substrate. The magnetic layer is subjected to a patterning process in which selected portions of the surface of the magnetic layer are altered such that the altered portions have different magnetic properties from the non-altered portions without changing the topography of the substrate. A protective layer and a lubricant layer are deposited over the patterned magnetic layer. The patterning is accomplished through a number of processes that expose substrates to energy of varying forms. Apparatus and methods disclosed herein enable processing of two major surfaces of a substrate simultaneously, or sequentially by flipping. In some embodiments, magnetic properties of the substrate surface may be uniformly altered by plasma exposure and then selectively restored by exposure to patterned energy.

Abstract: An electrostatic chuck having either a conformal or non-conformal upon a surface for supporting a substrate. The coating reduces a of particles generated by the electrostatic chuck.

Abstract: An electrostatic chuck having either a conformal or non-confomal coating upon a surface for supporting a substrate. The coating reduces a number of particles generated by the electrostatic chuck.

Abstract: High energy neutral contamination in an ion implanter can be caused by beam ions neutralised as they are temporarily accelerated at an electrode before being decelerated again to the desired implant energy. This occurs for example in the decel lens arrangement which includes an electrode at a relatively high negative potential to provide the required focusing. The level of this contamination is monitored by measuring the current drain on this negative field electrode.

Abstract: Method and apparatus for the control of the rate of emission of electrons added to an ion implantation beam to neutralize charging effects on semiconductor wafers being processed. A net charging current, or equivalent voltage, is sensed continuously, but is sampled only when a selected wafer, or multiple selected wafers, are positioned to receive the entire cross section of the ion beam. The sampled charging current is used to control the addition of charge-neutralizing electrons to the ion beam, thereby eliminating problems that ensue from the use of an averaged charging current that is sensed without regard to the relative beam position or the number of wafers being processed.